PATENT ABSTRACT
Improved light receiving members which are characterized by having an special surface layer formed of a non-monocrystalline material containing tetrahedrally bonded boron nitride or a non-monocrystalline material containing said boron nitride and trihedrally bonded boron nitride in mingled state or by having an especial surface layer constituted with a lower layer formed of a non-monocrystalline material containing tetrahedrally bonded boron nitride and an upper layer formed of a non-monocrystalline material containing tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state. The improved light receiving members excel particularly in moisture resistance, repeating use characteristic, electrical voltage withstanding property environmental use characteristic and durability. 
     And the improved light receiving member are particularly advantageous when used as an image-making member in electrophotography since they always exhibit substantially stable electric characteristics without depending upon the working circumstances, maintain a high photosensitivity and a high S/N ratio, do not invite any undesirable influence due to residual voltage even when used repeatedly for a long period of time, cause either defective image nor image flow and have a wealth of cleaning properties.

PATENT DESCRIPTION
FIELD OF THE INVENTION 
     This invention relates to the improvements in the light receiving member comprising a substrate and a light receiving layer having at least a photoconductive layer formed of an amorphous material containing silicon atom as the main layer constituent and a surface layer. 
     More particularly, it relates to an improved light receiving member suited especially for use in electrophotography which has a light receiving layer having a surface layer formed of an amorphous material containing tetrahedrally bonded boron nitride or both said boron nitride and trihedrally bonded boron nitride being disposed on said photoconductive layer. 
     BACKGROUND OF THE INVENTION 
     For the light receiving members for use in electrophotography and the like, the public attention has been focused on such light receiving members that have a photoconductive layer formed of an amorphous material containing silicon atom as the main layer constituent and hydrogen atom or/and halogen atom [hereinafter referred to as &#34;A--Si(H,X)&#34;]  as disclosed in Unexamined Japanese Patent Publications Sho. 54(1979)-86341 and Sho. 56(1981)-83746, since said photoconductive layer has a high Vickers hardness in addition to having an excellent matching property in the photosensitive region in comparison with that in other kinds of light receiving member and it is not harmful to living things as well as man upon the use. 
     By the way, in any case, such light receiving member comprises a substrate and a photoconductive layer formed of A--Si(H,X). In this respect, it is known to provide a surface layer on the photoconductive layer, which functions to prevent the photoconductive layer from being injected by charges from its free surface side when it is engaged in charging process and to improve the moisture resistance, repeating use characteristics, breakdown voltage resistance, use environmental characteristics and durability of the photoconductive layer, and further in order to make it possible to maintain the quality of the images to be obtained for a long period of time. 
     And there have been made various proposals to form such surface layer using a high resistant and phototransmissive non-monocrystalline material such as amorphous material and polycrystalline material. 
     Among those proposals, there is a proposal to form such surface layer using a boron-nitrogen series amorphous material as disclosed in Unexamined Japanese Patent Publications Sho. 59(1984)12448 and Sho. 60(1985)-61760. 
     However, the boron(B)-nitrogen(N) series amorphous materials to form the foregoing surface layer which are disclosed in said publications are: boron atom and nitrogen atom are contained in unevenly distributed state and in addition, in large amount of hydrogen atom is contained; B--H bond, N--H bond and B--B bond are present in abundance; and the presence of B--N bond is slight and three dimensional structure by B--N bond is little present. 
     Because of this, for the light receiving members disclosed in said publications which has a surface layer formed of said boron-nitrogen series amorphous material, there are still unresolved problems that the surface layer is apt to be easily deteriorated not only with corona discharge in the charging process but also due to various mechanical actions during the contacts with a cleaning blade or other members of the device and as the layer deteriorates, it loses the functions required therefor. In addition to the above problems, the foregoing light receiving member has other problems that it is insufficient in charging efficiency so that it often brings about defective images such as those accompanied with undesired ghosts in the case where it is used in an image-making device. 
     SUMMARY OF THE INVENTION 
     This invention is aimed at eliminating the foregoing problems principally relative to the surface layer in the conventional light receiving member and providing an improved light receiving member having a desirable surface layer which can continuously exhibit the original functions required therefor without accompaniment of the foregoing problems even in repeating use for a long period of time. 
     Another object of this invention is to provide an improved light receiving member for use in electrophotography which always maintains a stable and effective charging efficiency and makes it possible to obtain high quality images even in the case of repeating use for a long period of time. 
     The present inventors have conducted extensive studies for overcoming the foregoing problems on the conventional light receiving members and attaining the objects as described above and, as a result, have accomplished this invention on the findings as below described. 
     That is, the present inventors have experimentally confirmed that the composition of the above mentioned surface layer formed of the foregoing boron-nitrogen series amorphous material is the very factor in order to solve the foregoing problems in the conventional light receiving member. 
     In view of the above, the present inventors have firstly investigated about the situation of influences of various boron nitrides in the cases when they are incorporated into a surface layer of a light receiving member for use in electrophotography. 
     As a result, the findings as below mentioned were obtained and on the basis of those findings, the present inventors have come to the result of acknowledging that not all but only limited kinds of boron nitride are effectively usable as the constituent of said surface layer. 
     That is, one finding is that the hexagonal system boron nitride of which cordination number being 3 is of the same structure as graphite, very soft, and 2 for Mohs hardness, and that in the case where the surface layer is formed of such boron nitride, the resultant light receiving member will become such that is weak against the impacts of active substances such as ion, ozone, electron etc. which will be generated by electric corona and that is apt to be easily deteriorated to lose the functions required therefor when it is mechanically damaged due to contacts with cleaning blade or other members of the electrophotographic copying system. 
     Further, since the hexagonal system boron nitride is of a relatively low electrical resistance, the light receiving member having a surface layer containing such boron nitride is undesirably low for the charging efficiency so that it often bring about defective images as such accompanied with undesired ghosts. 
     Another finding is that the cubic system boron nitride of which cordination number being 4 is of a large Mohs hardness, sufficiently resistant not only against the impacts of the above mentioned active substances but also against mechanical impacts and large enough for electrical resistance, and that in the case where the surface layer is formed of such cubic system boron nitride, the resultant light receiving member will become such desirable one that has a sufficient discharging efficiency and can make high quality images. 
     In view of the above, as far as the strength is concerned, it can be said that the surface layer is desirable to be formed of an amorphous material containing the hexagonal system boron nitride. 
     However, related various factors as below mentioned should be taken into consideration for the preparation of a desirable light receiving member particularly for use in electrophotography. 
     That is, the image-making process using a light receiving member in electrophotographic copying system comprises, typically, corona charging, image exposing, image developing with toner, image transferring to a paper and light receiving member cleaning. In this respect, the surface of the light receiving member will come to contact with plural members respectively of a different quality of the material in each step. 
     Therefore, the quality of an image to be transferred to a paper will largely depend upon whether the contact of the light receiving member with the respective members in the respective steps is suitable or not. For instance, in the case of the cleaning step using a blade, when the surface of the light receiving member is excessively hard, the blade will be worn away at an early stage and as a result, cleaning deficiency is apt to occur. And in that case, since the blade will be short-lived, the maintenance expenses of the copying system eventually become costly. On the other hand, in the case where the surface of the light receiving member is excessively soft, it is easily shaved by the blade to result in bringing about undesirable defects on an image to be made and other than this, the blade will be short-lived. Therefore, the maintenance expenses of the copying system eventually become costly also in this case. 
     In view of the above, it is necessary for the hardness of the surface of the light receiving member to be decided while having due regards on the harmonization thereof with the hardnesses of the respective members with which the light receiving member will contact in the respective steps of the above mentioned image-making process in electrophotographic copying system. Particularly in the case where the surface layer of the light receiving member is tried to form using the foregoing cubic system boron nitride, further appropriate improvements are required in the respective members in the respective steps of the above mentioned image-making process. 
     As a result of further continued studies on the basis of the above findings, the present inventors have come to obtain an acknowledge that either in the case where the surface layer of the light receiving member is made to be such that is formed of a non-monocrystalline material containing at least tetrahedrally bonded boron nitride or both tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state or in the case where the surface layer is made to be such that is constituted with a lower layer formed of a non-monocrystalline material containing tetrahedrally bonded boron nitride and an upper layer formed of a non-monocrystalline material containing tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state, the resultant light receiving member having any of the above surface layers becomes to have a desirable harmonization between the hardness of the surface of the light receiving member and the hardnesses of the respective members of the respective steps of the image-making process in electrophotographic copying system. 
     This invention has been completed based on the foregoing various findings, and it typically concerns an improved light receiving member comprising a substrate and a light receiving layer having at least a photoconductive layer formed of an amorphous material containing silicon atom as the main constituent atom and at least one kind atom selected from hydrogen atom and halogen atom and a surface layer, which is characterized in that said surface layer is formed of (1) a non-monocrystalline material containing tetrahedrally bonded boron nitride or (2) a non-monocrystalline material containing tetrahedrally bonded boron nitride and trihedrally bonded boron nitride, or is constituted with a lower layer formed of a non-monocrystalline material containing tetrahedrally bonded boron nitride and an upper layer formed of a non-monocrystalline material containing trihedrally bonded boron nitride in mingled state. 
     And in a preferred embodiment of the improved light receiving member according to this invention, the above mentioned surface layer may further contain dopants, either p-type or n-type. In that case, there is provided a further desirable light receiving member which can exhibit additional functions to prevent accumulation of charges in the surface layer after image exposure and also to further effectively prevent the occurrence of problems relative to image flow and residual voltage. 
     That is, in the case of the conventional light receiving member, the accumulation of charges often occurs in the surface layer after image exposure and the charges accumulated move horizontally near the interface between the surface layer and the photoconductive layer to thereby invite the occurrence of image flow on the resultant image. However, according to the light receiving member having of this invention which has such surface layer containing dopants, either p-type or n-type, charges which are moving into the surface layer after image exposure are mobilized to the free surface of the surface layer so that the occurrence of the problems relative to image flow and also to residual voltage which is often found on the conventional light receiving member can be effectively prevented. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1(A) through FIG. 1(I) are schematic views illustrating the typical layer constitution of a representative light receiving member according to this invention; 
     FIG. 1(A&#39;) through FIG. 1(I&#39;) are schematic views illustrating modifications of the light receiving members shown in FIG. 1(A) through FIG. 1(I). 
     FIG. 2 is a schematic explanatory view of a glow discharging fabrication apparatus for preparing the light receiving member of this invention; and 
     FIG. 3 and FIG. 4 are schematic fragmentary sectional views of a substrate which can be used in the light receiving member of this invention. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     Representative embodiments of the light receiving member according to this invention will now be explained more specifically referring to the drawings. The description is not intended to limit the scope of this invention. 
     Representative light receiving members for use in electrophotography according to this invention are as shown in FIG. 1(A) through FIG. 1(I) and also in FIG. 1(A&#39;) through FIG. 1(I&#39;), in which are shown substrate 101, photoconductive layer 102, surface layer 103, charge injection inhibition layer 104, long wavelength light absorptive layer (hereinafter referred to as &#34;IR absorptive layer&#34;) 105, contact layer 106, free surface 107, intermediate layer 108, lower constituent layer of the surface layer (hereinafter referred to as &#34;lower layer&#34;) 103&#39; and upper constituent layer of the surface layer (hereinafter referred to as &#34;upper layer&#34;) 103&#34;. 
     FIG. 1(A) and FIG. 1(A&#39;) are schematic views illustrating typical representative layer constitutions of this invention, which are shown: (1) the light receiving member comprising the substrate 101 and the light receiving layer constituted by the photoconductive layer 102 and the surface layer 103 having the free surface 107 [FIG. 1(A)]; and (2) a modification of the light receiving member (1) of which surface layer 103 being constituted by lower layer 103&#39; and upper layer 103&#34; having the free surface 107 [FIG. 1(A&#39;)]. 
     FIG. 1(B) and FIG. 1(B&#39;) are schematic views illustrating another representative layer constitutions of this invention, which are shown: (3) the light receiving member comprising the substrate 101 and the light receiving layer constituted by the charge injection inhibition layer 104, the photoconductive layer 102 and the surface layer 103 having the free surface 107 [FIG. 1(B)]; and (4) a modification of the light receiving member (3) of which surface layer 103 being constituted by lower layer 103&#39; and upper layer 103&#34; having the free surface 107 [FIG. 1(B&#39;)]. 
     FIG. 1(C) and FIG. 1(C&#39;) are schematic views illustrating another representative layer constitutions of this invention, which are shown: (5) the light receiving member comprising the substrate 101 and the light receiving layer constituted by the IR absorptive layer 105, the photoconductive layer 102 and the surface layer 103 having the free surface 107 [FIG. 1(C)]; and (6) a modification of the light receiving member (5) of which surface layer 103 being constituted by lower layer 103&#39; and upper layer 103&#34; having the free surface 107 [FIG. 1(C&#39;)]. 
     FIG. 1(D) and 1(D&#39;) are schematic views illustrating another representative layer constitutions of this invention, which are shown: (7) the light receiving member comprising the substrate 101 and the light receiving layer constituted by the contact layer 106, the photoconductive layer 102 and the surface layer 103 having the free surface 107 [FIG. 1(D)]; and (8) a modification of the light receiving member (7) of which surface layer being constituted by lower layer 103&#39; and upper layer 103&#34; having the free surface 107 [FIG. 1(D&#39;)]. 
     FIG. 1(E) and FIG. 1(E&#39;) are schematic views illustrating another representative layer constitutions of this invention, which are shown: (9) the light receiving member comprising the substrate 101 and the light receiving layer constituted by the charge injection inhibition layer 104, the contact layer 106, the photoconductive layer 102 and the surface layer 103 having the free surface 107 [FIG. 1(E)]; and (10) a modification of the light receiving member (9) of which surface layer being constituted by lower layer 103&#39; and upper layer 103&#34; having the free surface 107 [FIG. 1(E&#39;)]. 
     FIG. 1(F) and FIG. 1(F&#39;) are schematic views illustrating another representative layer constitutions of this invention, which are shown: (11) the light receiving member comprising the substrate 101 and the light receiving layer constituted by the IR absorptive layer 105, the contact layer 106, the photoconductive layer 102 and the surface layer 103 having the free surface 107 [FIG. 1(F)]; and (12) a modification of the light receiving member (11) of which surface layer being constituted by lower layer 103&#39; and upper layer 103&#34; having the free surface 107 [FIG. 1(F&#39;)]. 
     FIG. 1(G) and FIG. 1(G&#39;) are schematic views illustrating another representative layer constitutions of this invention, which are shown: (13) the light receiving member comprising the substrate 101 and the light receiving layer constituted by the IR absorptive layer 105, the charge injection inhibition layer 104, the photoconductive layer 102 and the surface layer 103 having the free surface 107 [FIG. 1(G)]; and (14) a modification of the light receiving member (13) of which surface layer 103 being lower layer 103&#39; and upper layer 103&#34; having the free surface 107 [FIG. 1(G&#39;)]. 
     FIG. 1(H) and FIG. 1(H&#39;) are schematic views illustrating another representative layer constitutions of this invention, which are shown: (15) the light receiving member comprising the substrate 101 and the light receiving layer constituted by the IR absorptive layer 105, the charge injection inhibition layer 104, the contact layer 106, the photoconductive layer 102 and the surface layer 103 having the free surface 107 [FIG. 1(H)]; and (16) a modification of the light receiving member (15) of which surface layer 103 being constituted by lower layer 103&#39; and upper layer 103&#34; having the free surface 107 [FIG. 1(H&#39;)]. 
     FIG. 1(I) and FIG. 1(I&#39;) are schematic views illustrating another representative layer constitutions of this invention, which are shown: (17) the light receiving member comprising the substrate 101 and the light receiving layer constituted by the charge injection inhibition layer 104, the photoconducting layer 102, the intermediate layer 108 and the surface layer 103 having the free surface 107 [FIG. 1(I)]; and (18) a modification of the light receiving member (17) of which surface layer 103 being constituted by lower layer 103&#39; and upper layer 103&#34; having the free surface 107 [FIG. 1(I&#39;)]. 
     SUBSTRATE 101 
     The substrate 101 for use in this invention may either be electroconductive or insulative. The electroconductive substrate can include, for example, metals such as NiCr, stainless steels, Al, Cr, Mo, Au, Nb, Ta, V, Ti Pt and Pb or the alloys thereof. 
     The electrically insulative substrate can include, for example, films or sheets of synthetic resins such as polyester, polyethylene, polycarbonate, cellulose acetate, polypropylene, polyvinyl chloride, polyvinylidene chloride, polystyrene, and polyamide, glass, ceramic and paper. It is preferred that the electrically insulative substrate is applied with electroconductive treatment to at least one of the surfaces thereof and disposed with a light receiving layer on the thus treated surface. 
     In the case of glass, for instance, electroconductivity is applied by disposing, at the surface thereof, a thin film made of NiCr, Al, Cr,, Mo, Au, Ir, Nb, Ta, V, Ti, Pt, Pd, In 2  O 3 , SnO 2 , ITO (In 2  O 3  +SnO 2 ), etc. In the case of the synthetic resin film such as a polyester film, the electroconductivity is provided to the surface by disposing a thin film of metal such as NiCr, Al, Ag, Pv, Zn, Ni, Au, Cr, Mo, Ir, Nb, Ta, V, Tl and Pt by means of vaccum deposition, electron beam vapor deposition, sputtering, etc., or applying lamination with the metal to the surface. The substrate may be of any configuration such as cylindrical belt-like or plate-like shape, which can be properly determined depending on the application uses. 
     The thickness of the substrate is properly determined so that the light receiving member as desired can be formed. 
     In the case where flexibility is required for the light receiving member, it can be made as thin as possible within a range capable of sufficiently providing the function as the substrate. However, the thickness is usually greater than 10 μm in view of the fabrication and handling or mechanical strength of the substrate. 
     And, it is possible for the surface of the substrate to be uneven in order to eliminate occurrence of defective images caused by a so-called interference fringe pattern being apt to appear in the formed images in the case where the image making process is conducted using coherent monochromatic light such as laser beams. 
     CHARGE INJECTION INHIBITION LAYER 104 
     The charge injection inhibition layer is to dispose under the photoconductive layer 102. 
     The charge injection inhibition layer in the light receiving member is constituted with an A--Si(H,X) material containing group III element as a p-type dopant or group V element as an n-type dopant [hereinafter referred to as &#34;A--Si(III,V):(H,X)&#34;], a poly-Si(H,X) material containing group III element or group V element [hereinafter referred to as &#34;poly-Si(III,V):(H,X)&#34;] or a non-monocrystalline material containing the above two materials [hereinafter referred to as &#34;Non-Si(III,V):(H,X)&#34;]. 
     The charge injection inhibition layer in the light receiving member of this invention functons to maintain an electric charge at the time when the light receiving member is engaged in electrification process and also to contribute to improving the photoelectrographic characteristics of the light receiving member. 
     In view of the above, to incorporate either the group III element or the group V element into the charge injection inhibition layer is an important factor to efficiently exhibit the foregoing functions. 
     Specifically, the group III element can include B (boron), Al (aluminum), Ga (gallium), In (indium) and Tl (thallium). The group V element can include, for example, P (phosphor), As (arsenic), Sb (antimony) and Bi (bismuth). Among these elements, B, Ga, P and As are particularly preferred. 
     And the amount of either the group III element or the group V element to be incorporated into the charge injection inhibition layer is preferably 3 to 5×10 4  atomic ppm, more preferably 50 to 1×10 4  atomic ppm, and most preferably 1×10 2  to 5×10 3  atomic ppm. 
     As for the hydrogen atoms(H) and the halogen atoms(X) to be incorporated into the charge injection inhibition layer, the amount of the hydrogen atoms(H), the amount of the halogen atoms(X) or the sum of the amounts of the hydrogen atoms and the halogen atoms(H+X) is preferably 1×10 3  to 7×10 5  atomic ppm, and most preferably, 1×10 3  to 2×10 5  atomic ppm in the case where the charge injection inhibition layer is constituted with a poly-Si(III,V):(H,X) material and 1×10 4  to 6×10 5  atomic ppm in the case where the charge injection inhibition layer is constituted with an A--Si(III,V):(H,X) material. 
     Further, it is possible to incorporate at least one kind atoms selected from oxygen atoms, nitrogen atoms and carbon atoms into the charge injection inhibition layer aiming at improving the bondability of the charge injection inhibition layer not only with the substrate but also with other layer such as the photoconductive layer and also improving the matching of an optical band gap(Egopt). 
     In this respect, the amount of at least one kind atoms selected from oxygen atoms, nitrogen atoms and carbon atoms to be incorporated into the charge injection inhibition layer is preferably 1×10 -3  to 50 atomic %, more preferably 2×10 -3  to 40 atomic %, and most preferably 3×10 -3  30 atomic %. 
     The thickness of the charge injection inhibition layer in the light receiving member is an important factor also in order to make the layer to efficiently exhibit its functions. 
     In view of the above, the thickness of the charge injection inhibition layer is preferably 0.03 to 15 μm, more preferably 0.04 to 10 μm, and most preferably 0.05 to 8 μm. 
     IR ABSORPTIVE LAYER 105 
     The IR absorptive layer 105 in the light receiving member of this invention is to dispose under the photoconductive layer 102 or the charge injection inhibition layer 104. 
     The IR absorptive layer in the light receiving member of this invention functions to effectively absorb the long wavelength light remained unabsorbed in the photoconductive layer to thereby prevent the appearance of interference phenomena due to reflection of long wavelength light at the substrate surface. 
     The IR absorptive layer 105 is constituted with an A--Si(H,X) material containing germanium atoms(Ge) or/and tin atoms(Sn) [hereinafter referred to as &#34;A--si(Ge,Sn) (H,X)&#34;], a poly--Si(H,X) material containing germanium atoms (Ge) or/and tin atoms(Sn) [hereinafter referred to as &#34;poly--Si(Ge,Sn) (H,X)&#34;]or a non-monocrystalline material containing at least one of the above two materials [hereinafter referred to as &#34;Non--Si(Ge,Sn) (H,X)&#34;]. 
     As for the germanium atoms(Ge) and the tin atoms(Sn) to be incorporated into the IR absorptive layer, the amount of the germanium atoms(Ge), the amount of the tin atoms(Sn) or the sum of the amounts of the germanium atoms and the tin atoms(Ge+Sn) is preferably 1 to 1×10 6  atomic ppm, more preferably 1×10 2  to 9×10 5  atomic ppm, and most preferably, 5×10 2  to 8×10 5  atomic ppm. 
     As for the hydrogen atoms(H) and the halogen atoms(X) to be incorporated into the IR absorptive layer, the amount of the hydrogen atoms(H), the amount of the halogen atoms(X) or the sum of the amounts of the hydrogen atoms and the halogen atoms(H+X) is preferably 1×10 3  to 3×10 5  atomic ppm, and most preferably, 1×10 3  to 2×10 5  atomic ppm in the case where it is constituted with a poly--Si(Ge,Sn) (H,X) material and 1×10 4  to 6×10 5  atomic ppm in the case where it is constituted with an A--Si(Ge,Sn) (H,X) material. 
     And, the thickness of the IR absorptive layer 105 is preferably 0.05 to 25 μm, more preferably 0.07 to 20 μm, and most preferably 0.1 to 15 μm. 
     CONTACT LAYER 106 
     The contact layer 106 in the light receiving member of this invention is to dispose under the photoconductive layer. 
     The main object of disposing the contact layer in the light receiving member of this invention is to enhance the bondability between the substrate and the photoconductive layer, between the charge injection inhibition layer and the photoconductive layer or between the IR absorptive layer and the photoconductive layer. 
     The contact layer 106 is constituted with an A--Si(H,X) material containing at least one kind atom selected from oxygen atom, carbon atom and nitrogen atom [hereinafter referred to as &#34;A--Si(O,C,N) (H,X)&#34;], a poly--Si(H,X) material containing at least one kind atom selected from oxygen atom, carbon atom and nitrogen atom [hereinafter referred to as &#34;poly--Si(O,C,N) (H,X)&#34;] or a Non--Si(H,X) material containing at least one kind atom selected from oxygen atom, carbon atom and nitrogen atom [hereinafter referred to as &#34;Non--Si(O,C,N) (H,X)&#34;]. 
     In the light receiving member of this invention, the amount of nitrogen atoms, oxygen atoms, or carbon atoms to be incorporated in the contact layer is properly determined according to the use purposes. 
     However, the amount of one or more kind atoms of them to be contained in the contact layer is preferrably 1×10 2  to 9×10 5  atomic ppm and more preferrably 1×10 2  tp 4×10 5  atomic ppm. 
     As for the hydrogen atoms(H) and the halogen atoms(X) to be contained in the contact layer, the amount of the hydrogen atoms(H), the amount of the halogen atoms(X) or the sum of the amounts of the hydrogen atoms and the halogen atoms(H+X) is preferably 10 to 7×10 5  atomic ppm, and most preferably, 10 to 2×10 5  atomic ppm in the case where it is constituted with a poly--Si(O,C,N) (H,X) material, and 1×10 3  to 7×10 5  atomic ppm in the case where it is constituted with an A--Si(O,C,N) (H,X) material. 
     And the thickness of the contact layer 106 is preferably 20 Å to 5 μm, more preferably 50 Å to 3 μm, and most preferably, 100 Å to 1 μm. 
     By the way, in the light receiving member of this invention, it is possible to selectively combine the foregoing charge injection inhibition layer 104, IR absorptive layer 105 and contact layer 106. 
     Representative embodiments in that case are shown in FIG. 1(E) to 1(H) and FIGS. 1(E&#39;) to 1(H&#39;). 
     Further, in the light receiving member of this invention, it is possible to make the foregoing charge injection inhibition layer 104 or IR absorptive layer to be such that can function not only as that layer but also as the contact layer. 
     In that case, the object can be attained by incorporating at least one kind atom selected from oxygen atom, carbon atom and nitrogen atom into the corresponding layer. 
     Further in addition, it is also possible to make either the foregoing IR absorptive layer 105 or the foregoing charge injection inhibition layer to be such that can exhibit the functions of the two layers by incorporating the group III element or the group V element into the foregoing IR absorptive layer or by incorporating germanium atom or tin atom into the foregoing charge injection inhibition layer. 
     Now, for the formation of each of the above mentioned constitutent layers, that is, charge injection inhibition layer 104, IR absorptive layer 105 and contact layer 106 of the light receiving member of this invention, any of the known film forming processes such as thermal induced chemical vapor deposition process, plasma chemical vapor deposition process, reactive sputtering process and light induced chemical vapor deposition process can be selectively employed. And among these processes, the plasma chemical vapor deposition process is the most appropriate. 
     For instance, in the case of forming such layer constituted with a poly--Si(H,X) series material by means of plasma chemical vapor deposition (commonly abbreviated to &#34;plasma CVD&#34;), the layer forming operation is practiced while maintaining the substrate at a temperature from 400° to 450° C. in a deposition chamber. 
     In an alternative process, firstly, an amorphous-like film is formed on the substrate being maintained at about 250° C. in a deposition chamber by means of plasma CVD, and secondly the resultant film is annealed by heating the substrate at a temperature of 400° to 450° C. for about 20 minutes or by irradiating laser beam onto the substrate for about 20 minutes to thereby form said layer. 
     PHOTOCONDUCTIVE LAYER 102 
     The photoconductive layer in the light receiving member according to this invention is constituted with an A--Si(H,X) material or a germanium(Ge) or tin(Sn) containing A--Si(H,X) material [hereinafter referred to as &#34;A--Si(Ge,Sn) (H,X)&#34;]. The photoconductive layer 102 may contain the group III element or the group V element respectively having a relevant function to control the conductivity of the photoconductive layer, whereby the photosensitivity of the layer can be improved. 
     As the group III element or the group V element to be incorporated in the photoconductive layer 102, it is possible to use the same element as incorporated into the charge injection inhibition layer 104. It is also possible to use such element having an opposite polarity to that of the element to be incorporated into the charge injection inhibition layer. And, in the case where the element having the same polarity as that of the element to be incorporated into the charge injection inhibition layer is incorporated into the photoconductive layer 102, the amount may be lesser than that to be incorporated into the charge injection inhibition layer. 
     Specifically, the group III element can include B (boron), Al (aluminum), Ga (gallium), In (indium) and Ti (thallium), B and Ga being particularly preferred. The group V element can include, for example, P (phosphor), As (arsenic), Sb (antimony) and Bi (bismuth), P and Sb being particularly preferred. 
     The amount of the group III element or the group V element to be incorporated in the photoconductive layer 102 is preferably 1×10 -3  to 1×10 3  atomic ppm, more preferably, 5×10 -2  to 5×10 2  atomic ppm, and most preferably, 1×10 -1  to 2×10 2  atomic ppm. 
     The halogen atoms(X) to be incorporated in the layer in case where necessary can include fluorine, chlorine, bromine and iodine. And among these halogen atoms, fluorine and chlorine are particularly preferred. The amount of the hydrogen atoms(H), the amount of the halogen atoms(X) or the sum of the amounts for the hydrogen atoms and the haogen atoms(H+X) to be incorporate in the photoconductive layer is preferably 1 to 4×10 atomic %, more preferably, 5 to 3×10 atomic %. 
     Further, in order to improve the quality of the photoconductor layer and to increase it dark resistance, at least one kind atom selected from oxygen atom, carbon atom and nitrogen atom can be incorporated in the photoconductive layer. The amount of these atoms to be incorporated in the photoconductive layer is preferably 1×10 -3  to 50 atomic ppm, more preferably 2×10 -3  to 40 atomic ppm, and, most preferably, 3×10 -3  to 30 atomic ppm. 
     The sensitivity of the photoconductive layer 102 in the light receiving member of this invention against long wavelength light such as laser beam can be further improved by incorporating germanium atom(Ge) or/and tin atom(Sn) thereinto. 
     The amount of the germanium atom or/and the tin atoms in that case is preferred to be in the range of 1 to 9.5×10 5  atomic ppm. 
     The thickness of the photoconductive layer 102 is an important factor in order to effectively attain the object of this invention. The thickness of the photoconductive layer is, therefore, necessary to be carefully determined having due regards so that the resulting light receiving member becomes accompanied with desitred characteristics. 
     In view of the above, the thickness of the photoconductive layer 102 is preferably 3 to 100 μm, more preferably 5 to 80 μm, and most preferably 7 to 50 μm. 
     SURFACE LAYER 103 
     The surface layer 103 in the light receiving member of this invention has a free surface 107 and is disposed on the foregoing photoconductive layer 102. 
     And, the surface layer 103 in the light receiving member of this invention serves not only to improve various characteristics commonly required for a light receiving member such as the humidity resistance, deterioration resistance upon repeating use, breakdown voltage resistance, use-environmental characteristics and durability of the light receiving member but also to effectively prevent electric charges from being injected into the photoconductive layer 102 from the side of fthe free surface 107 at the time when the light receiving layer is engaged in the charging process. 
     The surface layer 103 in the light receiving member of this invention is formed of: (1) a non-monocrystalline material or a polycrystalline material respectively containing tetrahedrally bonded boron nitride [the former will be hereinafter referred to as &#34;Non--BN&#34; or &#34;A--BN&#34; and the latter will be hereinafter referred to as &#34;poly--BN&#34;] or (2) a Non--BN material containing trihedrally bonded boron nitride and tetrahedrally bonded boron nitride in mingled state, or (3) is constituted with a lower constituent layer 103&#39; formed of a Non-BN material containing tetrahdedrally bonded boron nitride and an upper constituent layer 103&#34; containing trihedrally bonded boron nitride and tetrahedrally bonded boron nitride in mingled state. 
     The surface layer 103 in the light receiving member of this invention may contain hydrogen atom(H) or/and halogen atom(X) [hereinafter referred to as &#34;A--BN(H, X)&#34;, &#34;poly-BN(H,X)&#34; or &#34;Non--BN(H,X)&#34;]. 
     The surface layer 103 in the light receiving member of this invention may contain dopants, either p-type or n-type. In this case, the surface layer further effectively serves to mobilize charges which are moving thereinto after the image exposure to its free surface to thereby prevent the occurrence of the problems relative to image flow and also to residual voltage which is often found on the conventional light receiving member. 
     The p-type dopant can include germanium atom(Ge), zinc atom(Zn) and a mixture of them (Ge+Zn). And, the n-type dopant can include silicon atom (Si), tin atom (Sn) or a mixture of them (Si+Sn). 
     The amount of such dopant to be contained in the surface layer 103 is preferably less than 1×10 3  atomic ppm, more preferably less than 7×10 2  atomic ppm, and most preferably 5×10 2  atomic ppm. 
     Now, the foregoing Non--BN(H,X) of which the surface layer 103 is formed can be expressed by th formula: [Bx(N 1-x )] 1-y  :(H,X) y  and the ratios of the layer constituents are desired to satisfy the following conditions: 
     (i) In the case of where the surface layer is formed of said Non--BN series material containing tetrahedrally bonded boron nitride; with respect to x; 
     preferably, 0.25≦x≦0.75, more preferably, 0.3≦x≦0.7, and most preferably, 0.4≦x≦0.6, and with respect to y; 
     preferably, 0.004≦y≦0.4, more preferably 0.005≦y≦0.3 and most preferably 0.01≦y≦0.2. 
     (ii) In the case where the surface layer is formed of said Non--BN series material containing trihedrally bonded boron nitride and tetrahedrally bonded boron nitride in mingled state; with respect to x; 
     preferably, 0.1≦x≦0.9, more preferably, 0.2≦x≦0.8, and most preferably, 0.3≦x≦0.7, and 
      with respect to y; 
     preferably 0.004≦y≦0.4, more preferably 0.005≦y≦0.3, and most preferably, 0.01≦y≦0.2. 
     The thickness of the surface layer 103 in the light receiving member of this invention is appropriately determined depending upon the desired purpose. 
     It is, however, also necessary that the thickness be determined in view of relative and organic relationship in accordance with the amounts of the constituent atoms to be contained in the layer or the characteristics required in the relationship with the thickness of other layer. Further, it should be determined also in economical viewpoints such as productivity or mass productivity. 
     In view of the above, the thickness of the surface layer 103 is preferably 3×10 -3  to 30 μm, more preferably, 4×10 -3  to 20 μm, and, most preferably, 5×10 -3  to 10 μm. 
     INTERMEDIATE LAYER 108 
     The intermediate layer 108 in the light receiving member of this invention is to dispose between the photoconductive layer 102 and the surface layer 103 and it principally serves to improve breakdown voltage resistance of the light receiving layer. 
     The intermediate layer 108 is formed of either an A--Si(H,X) material or a poly-Si(H,X) material respectively containing carbon atom in an amount of preferably 20 to 90 atomic %, more preferably 30 to 85 atomic %, and most preferably, 40 to 80 atomic %. 
     As for the hydrogen atom(H) and halogen atom(X) to be optionally contained in the intermediate layer, the amount of hydrogen atoms or halogen atoms, or the sum of the amount of hydrogen atoms and the amount of halogen atoms is preferably 1 to 7×10 atomic %, more preferably 2 to 65 atomic %, and most preferably, 5 to 60 atomic %. 
     The thickness of the intermediate layer 108 is preferably 3×10 -2  to 30 μm, more preferably 4×10 -2  to 20 μm, and most preferably, 5×10 -2  to 10 μm. 
     FORMATION OF LAYERS 
     The method of forming the light receiving layer of the light receiving member will be now explained. 
     Each layer to constitute the light receiving layer of the light receiving member of this invention can be properly prepared by vacuum deposition method utilizing the discharge phenomena such as glow discharging, reactive sputtering and ion plating processes wherein relevant raw material gases are selectively used. 
     These production methods are properly used selectively depending on the factors such as the manufacturing conditions, the installation cost required, production scale and properties required for the light receiving members to be prepared. The glow discharging method or sputtering method is suitable since the control for the condition upon preparing the light receiving members having desired properties are relatively easy, and hydrogen atoms, halogen atoms and other atoms can be introduced easily together with silicon atoms. The glow discharging method and the sputtering method may be used together in one identical system. 
     FORMATION OF SURFACE LAYER 
     Basically when a surface layer composed of Non--BH(H,X) is formed by the glow discharging process, a feed gas capable of supplying boron atoms(B), a feed gas capable of supplying nitrogen atoms(N) and an inert gas are introduced, if necessary, together with a feed gas for introducing hydrogen atoms(H) or/and a feed gas for introducing halogen atoms(X) into a deposition chamber the inner pressure of which can be reduced properly, glow discharge is generated in the deposition chamber, and a layer composed of Non--BN (H,X) to be the surface layer is formed on a substrate placed in the deposition chamber. 
     And in order to form a surface layer composed of a Non--BN(H,X) material containing dopants by the glow discharging process, basically, a feed gas to liberate boron atoms(B), a feed gas to liberate nitrogen atoms(N), either a feed gas to liberate silicon atoms(Si) or/and tin atoms (Sn) or a feed gas to liberate germanium atoms(Ge) or/and zinc atoms(Zn), and an inert gas are introduced, if necessary, together with a feed gas to liberate hydrogen atoms(H) or/and a feed gas to liberate halogen atoms(H) into a deposition chamber the inner pressure of which can be reduced properly, glow discharge is generated in the deposition chamber, and a layer composed of a Non--Bn(H,X) material containing dopants to be the surface layer is formed on a substrate placed in the deposition chamber. 
     The raw material for supplying B can include gaseous or gasifiable compounds such as B 2  H 6 , B 4  H 10 , B 5  H 9 , B 5  H 11 , B 6  H 12 , BF 3  and Bcl 3 . 
     The raw material for supplying N can include gaseous or gasifiable compounds such as N 2 , NH 3 , NF 2  Cl, NFCl 2 , NCl 3 , N 2  F 2 , N 2  F 4 , NH 2  Cl, NHF 2  and NH 2  F. 
     The raw material for supplying Si can include gaseous or gasifiable compounds such as SiH 4 , Si 2  H 6 , Si 3  H 8 , Si 4  H 10 , SiF 4  and Sicl 4 . 
     The raw material for supplying Sn can include gaseous or gasifiable compounds such as SnH 4 , SnF 4  and SnCl 4 . 
     The raw material for supplying Ge can include gaseous or gasificable germanium compounds such as GeH 4 , Ge 2  H 6  and GeF 4 . 
     The raw material for supplying Zn can include gaseous or gasifiable zinc compounds such as Zn(CH 3 ) 2 . 
     The raw material for supplying halogen atoms can include halogen gases such as F 2 , Cl 2 , I 2 , Br 2  and FCl. 
     The raw material for supplying hydrogen atoms can include gaseous or gasifiable compounds such as HF, HCl, HBr, HI, B 2  H 6 , B 4  H 10 , NH 3 , SiH 4 , Si 2  H 6 , SnH 4 , GeH 4  and Ge 2  H 6 . 
     In the case of forming a layer composed of a Non--BN (H,X) material containing tetrahedrally bonded boron nitride by the sputtering process, basically, a BN target is subjected to sputtering with gas plasmas in a gas atmosphere containing a raw material gas for supplying B which is diluted with an inert gas such as Ar gas in an appropriate sputtering deposition chamber the inner pressure of which can be reduced properly to thereby form said layer on a substrate placed in said chamber. 
     Further, the formation of a layer composed of a dopant containing Non--BN(H,X) material containing tetrahedrally bonded boron nitride may be practiced by using a BN target and by introducing a raw material gas for supplying Si or/and Sn or raw material gas for supplying Ge or/and Zn together with an inert gas such as Ar gas into the above sputtering deposition chamber to form plasma atmosphere and sputtering said BN target with the gas plasmas. 
     In the above case, it is possible to use a Zn target or a Ge target and to introduce a raw material gas for supplying B and a raw material gas for supplying N together with an inert gas such as Ar gas into the above sputtering deposition chamber. 
     The formation of a layer composed of a Non--BN(H,X) containing tetrahdedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state by the sputtering process may be practiced by using a BN target and by introducing a raw material gas for supplying N together with an inert gas such as He gas into the foregoing sputtering deposition chamber to form plasma atmosphere and sputtering said BN target. In this case, it is possible to form said layer by using a B target and by introducing a large amount of a raw material gas for supplying N together with said inert gas to form plasma atmosphere and sputtering said B target with gas plasmas. 
     The formation of a layer composed of a dopant containing Non--BN(H,X) containing tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state may be practiced by using a BN target and by introducing a raw material gas for supplying N and a raw material gas for supplying dopants together with an inert gas such as He gas into the foregoing sputtering deposition chamber to form plasma atmosphere and sputtering said BN target with gas plasmas. In this case, it is possible to form said layer by using a B target and introducing a large amount of a raw material gas for supplying N and a raw material gas for supplying dopants together with said inert gas into the foregoing sputtering deposition chamber to form plasma atmosphere and sputtering said B target with gas plasmas. 
     The conditions upon forming the surface layer 103 in the light receiving member of this invention, for example, the temperature of the substrate, the gas pressure in the deposition chamber and the electric discharging power are important factors for obtaining an objective surface layer having desired properties and they are properly selected while considering the functions of the layer to be formed. Further, since these layer forming conditions may be varied depending on the kind and the amount of each of the atoms contained in the layer, the conditions have to be determined also taking the kind or the amount of the atoms to be contained into consideration. 
     Specifically, in the case of forming a layer composed of a Non--BN(H,X) material containing tetrahedrally bonded boron nitride by plasma CVD method using high frequency of 13.56 MHz, the gas pressure in the deposition chamber is preferably 10 -2  to 10 Torr, more preferably 5×10 -2  to 2 Torr, and most preferably, 1×10 -1  to 1 Torr. The temperature of the substrate is preferably 50° to 700° C., and more preferably, 50° to 400° C. in the case of forming a layer composed of a Non--BN(H,X) series material, and 200° to 700° C. in the case of forming a layer compoed of a poly--BN(H,X) series material. 
     As for the electrical discharging power, it is preferably 0.01 to 5W/cm 2 , and most preferably, 0.02 to 2W/cm 2 . 
     Further, as for the flow ratios relative to the raw material gas for supplying b, the raw material gas for supplying N and Ar gas, the flow ratio B/N is controlled to be preferably 1/5 to 100/1, and most preferably 1/4 to 80/1, and at the same time, the flow ratio Ar/B+N is controlled to be preferably 1/10 to 100/1 and most preferably 1/7 to 80/1. 
     And in the case of forming the above mentioned layer by plasma CVD method using microwave of 2.45 GHz, the gas pressure in the deposition chamber is preferably 1×10 -4  to 2 Torr, more preferably 5×10 -4  to 1.0 Torr, and most preferably, 5×10 -4  to 0.7 Torr. The electrical discharging power is preferably 0.1 to 50 W/cm 2 , and most preferably, 0.2 to 30 W/cm 2 . 
     In this case, the temperature of the substrate and the flow ratios of the gases used are the same as those in the foregoing case using high frequency. 
     In the case of forming a layer composed of a Non--BN (H,X) material containing tetrahedrally bonded boron nitride by the sputtering process, the gas pressure in the deposition chamber is preferably 1×10 -4  to 1.0 Torr, and most preferably, 5×10 -4  to 0.7 Torr. The electrical charging power is preferably 0.01 to 10 W/cm 2 , and most preferably, 0.05 to 8 W/cm 2 . 
     In this case, the temperature of the substrate and the flow ratios of the gases used are the same as those in the foregoing case by plasma CVD method using high frequency. 
     In the case of forming a layer composed of a Non--BN (H,X) material containing tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state by plasma CVD method using high frequency of 13.56 MHz, the gas pressure in the deposition chamber is preferably 1×10 -2  to 10 Torr, more preferably 5×10 -2  to 2 Torr, and most preferably, 0.1 to 1 Torr. The temperature of the substrate is preferably 50° to 700° C., and more preferably, 50° to 400° C. in the case of forming a layer composed of a Non--BN(H,X) material containing tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state, and 200° to 700° C. in the case of forming a layer composed of a poly--BN(H,X) containing the above two kinds of boron nitride in mingled state. As for the electrical discharging power, it is preferably 0.05 to 5 W/cm 2 , and most preferably, 0.02 to 2 W/cm 2 . Further, as for the flow ratios relative to the raw material gas for supplying B, the raw material gas for supplying N and He gas, the ratio B/N is controlled to be preferably 1/100 to 5/1, and most preferably, 1/80 to 4/1, and at the same time, the flow ratio He/B+N is controlled to be 1/10 to 0. 
     In the case of forming a layer composed of a Non--BN (H,X) material containing tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state by plasma CVD method using microwave of 2.45 GHz, the gas pressure in the deposition chamber is preferably 1×10 -4  to 2 Torr, more preferably 5×10 -4  to 1.0 Torr, and most preferably, 5×10 -4  to 0.7 Torr. The electrical discharging power is preferably 0.1 to 50 W/cm 2 , and most preferably 0.2 to 30 W/cm 2 . And, in this case, the temperature of the substrate and the flow ratios of the gases used are the same as those in the foregoing case using high frequency. 
     In addition, in the case of forming a layer composed of a Non--BN(H,X) material containing tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state by the sputtering process, the gas pressure in the deposition chamber is preferably 1×10 -4  to 1.0 Torr, and most preferably, 5×10 -4  to 0.7 Torr. As for the electrical discharging power, it is preferably 0.01 to 10 W/cm 2  and most preferably, 0.05 to 8 W/cm 2 . In this case, the temperature of the substrate and the flow ratios of the gases used are the same as those in the case by plasma CVD method using high frequency. 
     FORMATION OF OTHER LAYERS 
     Basically, when a layer constituted with a--Si(H,X) is formed, for example, by the glow discharging process, gaseous starting material capable of supplying silicon atoms(Si) is introduced together with gaseous starting material for introducing hydrogen atoms(H) and/or halogen atoms(X) into a deposition chamber the inside pressure of which can be reduced, glow discharge is generated in the deposition chamber, and a layer composed of a--Si(H,X) is formed on the surface of a predetermined substrate disposed previously at a predetermined position. 
     The gaseous starting material for supplying Si can include gaseous or gasifiable silicon hydrides (silanes) such as SiH 4 , Si 2  H 6 , Si 4  H 10 , etc., SiH 4  and Si 2  H 6  being particularly preferred in view of the easy layer forming work and the good efficiency for the supply of Si. 
     Further, various halogen compounds can be mentioned as the gaseous starting material for introducing the halogen atoms and gaseous or gasifiable halogen compounds, for example, gaseous halogen, halides, inter-halogen compunds and halogen-substituted silane derivatives are preferred. Specifically, they can include halogen gas such as of fluorine, chlorine, bromine, and iodine; inter-halogen compounds such as BrF, ClF, ClF 3 , BrF 2 , BrF 3 , IF 7 , IC1, IBr, etc.; and silicon halides such as SiF 4 , Si 2  H 6 , SiC 4 , and SiBr 4 . The use of the gaseous or gasifiable silicon halide as described above is particularly advantageous since the layer constituted with halogen atom-containing a--Si can be formed with no additional use of the gaseous starting material for supplying Si. 
     The gaseous starting material usable for supplying hydrogen atoms can include those gaseous or gasifiable materials, for example, hydrogen gas halides such as HF, HCl, HBr, and HI, silicon hydrides such as SiH 4 , Si 2  H 6 , Si 3  H 8 , and Si 4  O 10 , or halogen-substituted silicon hydrides such as SiH 2  F 2 , SiH 2  I 2 , SiH 2  Cl 2 , SiHCl 3 , SiH 2  Br 2 , and SiHBr 3 . The use of these gaseous starting material is advantageous since the content of the hydrogen atoms(H), which are extremely effective in view of the control for the electrical or photoelectronic properties, can be controlled with ease. Then, the use of the hydrogen halide or the halogen-substituted silicon hydride as described above is particularly advantageous since the hydrogen atoms(H) are also introduced together with the introduction of the halogen atoms. 
     In the case of forming a layer comprising a--Si(H,X) by means of the reactive sputtering process or ion plating process, for example, by the sputtering process, the halogen atoms are introduced by introducing gaseous halogen compounds or halogen atom-containing silicon compounds into a deposition chamber thereby forming a plasma atmosphere with the gas. 
     Further, in the case of introducing the hydrogen atoms, the gaseous starting material for introducing the hydrogen atoms, for example, H 2  or gaseous silanes are described above are introduced into the sputtering deposition chamber thereby forming a plasma atmosphere with the gas. 
     For instance, in the case of the reactive sputtering process, a layer comprising a--Si(H,X) is formed on the support by using an Si target and by introducing a halogen atom-introducing gas and H 2  together with an inert gas such as He or Ar as required into a deposition chamber thereby forming a plasma atmosphere and then sputtering the Si target. 
     To form the layer of a--SiGe(H,X) by the glow discharge process, a feed gas to liberate silicon atoms(Si), a feed gas to liberate germanium atoms, and a feed gas to liberate hydrogen atoms(H) and/or halogen atoms(X) are introduced into an evacuatable deposition chamber, in which the glow discharge is generated so that a layer of a--SiGe(H,X) is formed on the properly positioned support. 
     The feed gases to supply silicon atoms, halogen atoms, and hydrogen atoms are the same as those used to form the layer of a--Si(H,X) mentioned above. 
     The feed gas to liberate Ge includes gaseous or gasifiable germanium halides such as GeH 4 , Ge 2  H 6 , Ge 3  H 8 , Ge 4  H 10 , Ge 5  H 12 , Ge 6  H 14 , Ge 7  H 16 , Ge 8  H 18 , and Ge 9  H 20 , with GeH 4 , Ge 2  H 6 , and Ge 3  H 8 , being preferable on account of their ease of handling and the effective liberation of germanium atoms. 
     To form the layer of a--SiGe(H,X) by the sputtering process, two targets (a silicon target and a germanium target) or a single target composed of silicon and germanium is subjected to sputtering in a desired gas atmosphere. 
     To form the layer of a--SiGe(H,X) by the ion-plating process, the vapors of silicon and germanium are allowed to pass through a desired gas plasma atmosphere. The silicon vapor is produced by heating polycrystal silicon or single crystal silicon held in a boat, and the germanium vapor is produced by heating polycrystal germanium or single crystal germanium held in a boat. The heating is accomplished by resistance heating or electron beam method (E.B. method). 
     In either case where the sputtering process or the ion-plating process is employed, the layer may be incorporated with halogen atoms by introducing one of the above-mentioned gaseous halides or halogen-containing silicon compounds into the deposition chamber in which a plasma atmosphere of the gas is produced. In the case where the layer is incorporated with hydrogen atoms, a feed gas to liberate hydrogen is introduced into the deposition chamber in which a plasma atmosphere of the gas is produced. The feed gas may be gaseous hydrogen, silanes, and/or germanium hydrides. The feed gas to liberate halogen atoms includes the above-mentioned halogen-containing silicon compounds. Other examples of the feed gas include hydrogen halides such as HF, HCl, HBr and HI; halogen-substituted silanes such as SiH 2  F 2 , SiH 2  I 2 , SiH 2  Cl 2 , SiHCl 3 , SiH 2  Br 2 , and SiHBr 3  ; germanium hydride halide such as GeHF 3 , GeH 2  F 2 , GeH 3  F, GeHCl 3 , GeH 2  Cl 2 , GeH 3  Cl, GeHBr 3 , GeH 2  Br 2 , GeH 3  Br, GeHI 3 , GeH 2  I 2 , and GeH 3  I; and germanium halides such as GeF 4 , GeCl 4 , GeBr 4 , GeI 4 , GeF 2 , GeCl 2 , GeBr 2 , and GeI 2 . They are in the gaseous form or gasifiable substances. 
     To form the light receiving layer composed of amorphous silicon containing tin atoms (hereinafter referred to as a--SiSn(H,X)) by the glow-discharge process, sputtering process, or ion-plating process, a starting material (feed gas) to release tin atoms(Sn) is used in place of the starting material to release germanium atoms which is used to form the layer composed of a--SiGe(H,X) as mentioned above. The process is properly controlled so that the layer contains a desired amount of tin atoms. 
     Examples of the feed gas to release tin atoms(Sn) include tin hydride(SnH 4 ) and tin halides (such as SnF 2 , SnF 4 , SnCl 2 , SnCl 4 , SnBr 2 , SnBr 4 , SnI 2 , and SnI 4 ) which are in the gaseous form or gasifiable. Tin halides are preferable because they form on the substrate a layer of a--Si containing halogen atoms. Among tin halides, SnCl 4 , is particularly preferable because of its ease of handling and its efficient tin supply. 
     In the case where solid SnCl 4  is used as a starting material to supply tin atoms(Sn), it should preferably be gasified by blowing (bubbling) an inert gas (e.g., Ar and He) into it while heating. The gas thus generated is introduced, at a desired pressure, into the evacuated deposition chamber. 
     The layer may be formed from an amorphous material a--Si(H,X) or a--Si(Ge,Sn)(H,X) which further contains the group III atoms or group V atoms, nitrogen atoms, oxygen atoms, or carbon atoms, by the glow-discharge process, sputtering process, or ion-plating process. In this case, the above-mentioned starting material for a--Si(H,X) or a--Si(Ge,Sn)(H,X) is used in combination with the starting materials to introduce the group III atoms or group V atoms, nitrogen atoms, oxygen atoms, or carbon atoms. The supply of the starting materials should be properly controlled so that the layer contains a desired amount of the necessary atoms. 
     If, for example, the layer is to be formed by the glow-discharge process from a--Si(H,X) containing atoms (O,C,N) or from a--Si(Ge,Sn)(H,X) containing atoms (O,C,N), the starting material to form the layer of a--Si(H,X) or a--Si(Ge,Sn)(H,X) should be combined with the starting material used to introduce atoms (O,C,N). The supply of these starting materials should be properly controlled so that the layer contains a desired amount of the necessary atoms. 
     The starting material to introduce the atoms(O,C,N) may be any gaseous substance or gasifiable substance composed of any of oxygen, carbon, and nitrogen. Examples of the starting materials used to introduce oxygen atoms(O) include oxygen(O 2 ), ozone(O 3 ), nitrogen dioxide(NO 2 ), nitrous oxide(N 2  O), dinitrogen trioxide(N 2  O 3 ), dinitrogen tetroxide(N 2  O 4 ), dinitrogen pentoxide(N 2  O 5 ), and nitrogen trioxide(NO 3 ). Additional examples include lower siloxanes such as disiloxane(H 3  SiOSiH 3 ) and trisiloxane(H 3  SiOSiH 2  OSiH 3 ) which are composed of silicon atoms(Si), oxygen atoms(O), and hydrogen atoms(H). Examples of the starting materials used to introduce carbon atoms include saturated hydrocarbons having 1 to 5 carbon atoms such as methane(CH 4 ), ethane (C 2  H 6 ), propane(C 3  H 8 ), n-butane(n--C 4  H 10 ), and pentane(C 5  H 12 ); ethylenic hydrocarbons having 2 to 5 carbon atoms such as ethylene(C 2  H 4 ), propylene(C 3  H 6 ), butene--1(C 4  H 8 ), butene-2 (C 4  H 8 ), isobutylene(C 4  H 8 ), and pentene(C 5  H 10 ); and acetylenic hydrocarbons having 2 to 4 carbon atoms such as acetylene (C 2  H 2 ), methyl acetylene(C 3  H 4 ), and butine(C 4  H 6 ). Examples of the starting materials used to introduce nitrogen atoms include nitrogen(N 2 ), ammonia(NH 3 ), hydrazine(H 2  NNH 2 ), hydrogen azide(HN 3 ), ammonium azide(NH 4  N 3 ), nitrogen trifluoride(F 3  N), and nitrogen tetrafluoride(F 4  N). 
     In the case of using the glow discharging process for forming the layer or layer region containing oxygen atoms, starting material for introducing the oxygen atoms is added to those selected from the starting materials as desired for forming the light receiving layer. As the starting material for introducing the oxygen atoms, most of those gaseous or gasifiable materials can be used that comprise at least oxygen atoms as the constituent atoms. 
     For instance, it is possible to use a mixture of gaseous starting material comprising silicon atoms(Si) as the constituent atoms, gaseous starting material comprising oxygen atoms(O) as the constituent atom and, as required, gaseous starting material comprising hydrogen atoms(H) and/or halogen atoms(X) as the constituent atoms in a desired mixing ratio, a mixture of gaseous starting material comprising silicon atoms(Si) as the constituent atoms and gaseous starting material comprising oxygen atoms(O) and hydrogen atoms(H) as the constituent atoms in a desired mixing ratio, or a mixture of gaseous starting material comprising silicon atoms(Si) as the constituent atoms and gaseous starting material comprising silicon atoms(Si), oxygen atoms(O) and hydrogen atoms(H) as the constituent atoms. 
     Further, it is also possible to use a mixture of gaseous starting material comprising silicon atoms (Si) and hydrogen atoms (H) as the constituent atoms and gaseous starting material comprising oxygen atoms (O) as the constituent atoms. 
     Specifically, there can be mentioned, for example, oxygen (O 2 ), ozone (O 2 ), nitrogen monoxide (NO), nitrogen dioxide (NO 2 ), dinitrogen oxide (N 2  O), dinitrogen trioxide (N 2  O 3 ), dinitrogen tetraoxide (N 2  O 4 ), dinitrogen pentoxide (N 2  O 5 ), nitrogen trioxide (NO 3 ), lower siloxanes comprising silicon atoms (Si), oxygen atoms (O) and hydrogen atoms (H) as the constituent atoms, for example, disiloxane (H 3  SiOSiH 3 ) and trisiloxane (H 3  SiOSiH 2  OSiH 3 ), etc. 
     In the case of forming the layer or layer region containing oxygen atoms by way of the sputtering process, it may be carried out by sputtering a single crystal or polycrystalline Si wafer or SiO 2  wafer, or a wafer containing Si and SiO 2  in admixture is used as a target and sputtered in various gas atmospheres. 
     For instance, in the case of using the Si wafer as the target, a gaseous starting material for introducing oxygen atoms and, optionally, hydrogen atoms and/or halogen atoms is diluted as required with a dilution gas, introduced into a sputtering deposition chamber, gas plasmas with these gases are formed and the Si wafter is sputtered. 
     Alternatively, sputtering may be carried out in the atmosphere of a dilution gas or in a gas atmosphere containing at least hydrogen atoms (H) and/or halogen atoms (X) as constituent atoms as a sputtering gas by using individually Si and SiO 2  targets or a single Si and SiO 2  mixed target. As the gaseous starting material for introducing the oxygen atoms, the gaseous starting material for introducing the oxygen atoms shown in the examples for the glow discharging process as described above can be used as the effective gas also in the sputtering. 
     The light receiving layer containing carbon atoms, for example, may be formed through the glow discharging process, by using a mixture of gaseous starting material comprising silicon atoms (Si) as the constituent atoms, gaseous starting material comprising carbon atoms (C) as the constituent atoms and, optionally, gaseous starting material comprising hydrogen atoms (H) and/or halogen atoms (X) as the constituent atoms in a desired mixing ratio, a mixture of gaseous starting material comprising silicon atoms (Si) as the constituent atoms and gaseous starting material comprising carbon atoms (C) and hydrogen atoms (H) as the constituent atoms also in a desired mixing ratio, a mixture of gaseous starting material comprising silicon atoms (Si) as the constituent atoms and gaseous starting material comprising silicon atoms (Si), carbon atoms (C) and hydrogen atoms (H) as the constituent atoms, or a mixture of gaseous starting material comprising silicon atoms (Si) and hydrogen atoms (H) as the constituent atoms and gaseous starting material comprising carbon atoms (C) as constituent atoms. 
     Those gaseous starting materials that are effectively usable herein can include gaseous silicon hydrides comprising C and H as the constituent atoms, such as silanes, for example, SiH 4 , Si 2  H 6 , Si 3  H 8  and Si 4  H 10 , as well as those comprising C and H as the constituent atoms, for example, saturated hydrocarbons of 1 to 4 carbon atoms, ethylenic hydrocarbons of 2 to 4 carbon atoms and acetylenic hydrocarbons of 2 to 3 carbon atoms. 
     Specifically, the saturated hydrocarbons can include methane (CH 4 ), ethane (C 2  H 6 ), propane (C 3  H 8 ), n-butane (n--C 4  H 10 ) and pentane (C 5  H 12 ), the ethylenic hydrocarbons can include ethylene (C 2  H 4 ), propylene (C 3  H 6 ), butene-1 (C 4  H 8 ), butene-2 (C 4  H 8 ), isobutylene (C 4  H 8 ) and pentene (C 5  H 10 ) and the acetylenic hydrocarbons can include acetylene (C 2  H 2 ), methylacetylene (C 3  H 4 ) and butine (C 4  H 6 ). 
     The gaseous starting material comprising Si, C and H as the constituent atoms can include silicided alkyls, for example, Si(CH 3 ) 4  and Si(C 2  H 5 ) 4 . In addition to these gaseous starting materials, H 2  can of course be used as the gaseous starting material for introducing H. 
     The layer or layer region constituted with a--SiC(H,X) may be formed through the sputtering process by using a single crystal or polycrystalline Si wafer, a C (graphite) wafer or a wafer containing a mixture of Si and C as a target and sputtering them in a desired gas atmosphere. 
     In the case of using, for example a Si wafer as a target, gaseous starting material for introducing carbon atoms, and hydrogen atoms and/or halogen atoms is introduced while being optionally diluted with a dilution gas such as Ar and He into a sputtering deposition chamber thereby forming gas plasmas with these gases and sputtering the Si wafer. 
     Alternatively, in the case of using Si and C as individual targets or as a single target comprising Si and C in admixture, gaseous starting material for introducing hydrogen atoms and/or halogen atoms as the sputtering gas is optionally diluted with a dilution gas, introduced into a sputtering deposition chamber thereby forming gas plasmas and sputtering is carried out. As the gaseous starting material for introducing each of the atoms used in the sputtering process, those gaseous starting materials used in the glow discharging process as described above may be used as they are. 
     In the case of using the glow discharging process for forming the layer or the layer region containing the nitrogen atoms, starting material for introducing nitrogen atoms is added to the material selected as required from the starting materials for forming the light receiving layer as described above. As the starting material for introducing the nitrogen atoms, most of gaseous or gasifiable materials can be used that comprise at least nitrogen atoms as the constituent atoms. 
     For instance, it is possible to use a mixture of gaseous starting material comprising silicon atoms (Si) as the constituent atoms, gaseous starting material comprising nitrogen atoms (N) as the constituent atoms and, optionally, gaseous starting material comprising hydrogen atoms (H) and/or halogen atoms (X) as the constituent atoms mixed in a desired mixing ratio, or a mixture of starting gaseous material comprising silicon atoms (Si) as the constituent atoms and gaseous starting material comprising nitrogen atoms (N) and hydrogen atoms (H) as the constituent atoms also in a desired mixing ratio. 
     Alternatively, it is also possible to use a mixture of gaseous starting material comprising nitrogen atoms (N) as the constituent atoms gaseous starting material comprising silicon atoms (Si) and hydrogen atoms (H) as the constituent atoms. 
     The starting material that can be used effectively as the gaseous starting material for introducing the nitrogen atoms (N) used upon forming the layer or layer region containing nitrogen atoms can include gaseous or gasifiable nitrogen, nitrides and nitrogen compounds such as azide compounds comprising N as the constituent atoms or N and H as the constituent atoms, for example, nitrogen (N 2 ), ammonia (NH 3 ), hydrazine (H 2  NNH 2 ), hydrogen azide (HN 3 ) and ammonium azide (NH 4  N 3 ). In addition, nitrogen halide compounds such as nitrogen trifluoride (F 3  N) and nitrogen tetrafluoride (F 4  N 2 ) can also be mentioned in that they can also introduce halogen atoms (X) in addition to the introduction of nitrogen atoms (N). 
     The layer or layer region containing the nitrogen atoms may be formed through the sputtering process by using a single crystal or polycrystalline Si wafer or Si 3  N 4  wafer or a wafer containing Si and Si 3  N 4  in admixture as a target and sputtering them in various gas atmospheres. 
     In the case of using a Si wafer as a target, for instance, gaseous starting material for introducing nitrogen atoms and, as required, hydrogen atoms and/or halogen atoms is diluted optionally with a dilution gas, introduced into a sputtering deposition chamber to form gas plasmas with these gases and the Si wafer is sputtered. 
     Alternatively, Si and Si 3  N 4  may be used as individual targets or as a single target comprising Si and Si 3  N 4  in admixture and then sputtered in the atmosphere of a dilution gas or in a gaseous atmosphere containing at least hydrogen atoms (H) and/or halogen atoms (X) as the constituent atoms as for the sputtering gas. As the gaseous starting material for introducing nitrogen atoms, those gaseous starting materials for introducing the nitrogen atoms described previously shown in the example of the glow discharging can be used as the effective gas also in the case of the sputtering. 
     In addition, in the case of forming a layer or layer region constituted with a--Si(H,X) containing the group III or group V atoms by using the glow discharging, sputtering or ion plating process, the starting material for introducing the group III or group V atoms are used together with the starting material for forming a--Si(H,X) upon forming the layer constituted with a--Si(H,X) as described above and they are incorporated while controlling the amount of them into the layer to be formed. 
     Referring specifically to the boron atom introducing materials as the starting material for introducing the group III atoms, they can include boron hydrides such as B 2  H 6 , B 4  H 10 , B 5  H 9 , B 5  H 11 , B 6  H 10 , B 6  H 12  and B 6  H 14  and boron halides such as BF 3 , BCl 3  and BBr 3 . In addition, AlCl 3 , CaCl 3 , Ga(CH 3 ) 2 , InCl 3 , TlCl 3  and the like can also be mentioned. 
     Referring to the starting material for introducing the group V atoms and, specifically to, the phosphor atom introducing materials, they can include, for example, phosphor hydrides such as PH 3  and P 2  H 6  and phosphor halide such as PH 4  I, PF 3 , PF 5 , PCl 3 , PCl 5 , PBr 3 , PBr 5  and PI 3 . In addition, AsH 3 , AsF 5 , AsCl 3 , AsBr 3 , AsF 3 , SbH 3 , SbF 3 , SbF 5 , SbCl 3 , SbCl 5 , BiH 3 , SiCl 3  and BiBr 3  can also be mentioned to as the effective starting material for introducing the group V atoms. 
     In the case of forming the respective constituent layers other than the surface layer of the light receiving layer in the light receiving member of this invention by means of the glow discharging, reactive sputtering or ion plating process, the amount of each of the layer constituent atoms to be contained in a layer to be formed is controlled by appropriately regulating the flow rate of each of the raw material gases and the flow ratio among the raw material gases to be introduced into the deposition chamber. 
     The conditions upon forming each of such layers, for example, the temperature of the substrate, the gas pressure in the deposition chamber and the electrical discharging power are important factors for obtaining a light receiving member having desired properties and they are properly selected while considering the functions of the layer to be formed. Further, since these layer forming conditions may be varied depending on the kind and the amount of each of the atoms contained in the layer, the conditions have to be determined also taking the kind or the amount of the atoms to be contained into consideration. 
     Specifically, in the case of forming a layer composed of an A--Si(H,X) material containing nitrogen atom, oxygen atom, carbon atom, etc., the temperature of the substrate is preferably 50° to 350° C., and more preferably, 50° to 250° C. The gas pressure in the deposition chamber is preferably 0.01 to 1 Torr, and most preferably, 0.1 to 0.5 Torr. And, the electrical discharging power is preferably 0.005 to 50 W/cm 2 , more preferably 0.01 to 30 W/cm 2 , and most preferably, 0.01 to 20 W/cm 2 . 
     And in the case of forming a layer composed of either an A--SiGe(H,X) material or an A--SiGe(M,X) containing the group III atom or the group V atom, the temperature of the substrate is preferably 50° to 350° C., more preferably, 50° to 300° C., and most preferably, 100° to 300° C. The gas pressure in the deposition chamber is preferably 0.01 to 5 Torr, more preferably 0.01 to 3 Torr, and most preferably, 0.01 to 1 Torr. And, the electrical discharging power is preferably 0.005 to 50 W/cm 2 , more preferably 0.01 to 30 W/cm 2 , and most preferably, 0.01 to 20 W/cm 2 . 
     However, the actual conditions for forming the layer such as temperature of the substrate, discharging power and the gas pressure in the deposition chamber can not usually the determined with ease independent of each other. Accordingly, the conditions optimal to the layer formation are desirably determined based on relative and organic relationships for forming the amorphous material layer having desired properties. 
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The invention will be described more specifically while referring to Examples 1 through 312, but the invention is not intended to limit the scope only to these Examples. 
     In each of the Examples, the light receiving layer was formed using the fabrication apparatus shown in FIG. 2 in accordance with the glow discharging process. 
     In the apparatus shown in FIG. 2, gas reservoirs 202, 203, 204, 205, 206, 241 and 247 are charged with raw material gases for forming the respective layers of the light receiving member of this invention, that is, for instance, SiH 4  gas (99.999% purity) in the reservoir 203, B 2  H 6  gas diluted with H 2  gas (99.999% purity, hereinafter referred to as &#34;B 2  H 6  /H 2  gas&#34; in the reservoir 203, NO gas (99.5% purity) in the reservoir 204, B 2  H 6  gas diluted with Ar gas (99.999% purity, hereinafter referred to as &#34;B 2  H 6  /Ar gas&#34;) in the reservoir 205, B 2  H 6  gas diluted with He gas (99.999% purity, hereinafter referred to as &#34;B 2  H 6  /He gas&#34;) in the reservoir 206, SiH 4  gas diluted with He gas (99.999% purity, hereinafter referred to as &#34;SiH 4  /He gas&#34;) in the reservoir 241 and NH 3  gas (99.999% purity) in the reservoir 247. 
     In the case for introducing halogen atoms (X) into a layer, the reservoir for SiH 4  is replaced by another reservoir for SiF 4  gas for instance. 
     Prior to the entrance of these gases into a deposition chamber 201, it is confirmed that valves for the reservoirs 202 through 206, 241 and 247 and a leak valve 235 are closed and that exit valves 217 through 221, 244 and 250, and sub-valves 232 and 233 are opened. Then, a main valve 234 is at first opened to evacuate the inside of the deposition chamber 201 and gas pipings. 
     Then, upon observing that the reading on the vacuum gauge 236 became about 5×10 -6  Torr, the sub-valves 232 and 233 and the exit valves 217 through 221, 244 and 250. 
     Now, reference is made to an example in the case of forming a light receiving layer on an Al cylinder as a substrate 237. 
     SiH 4  gas from the reservoir 202, B 2  H 6  /H 2  gas from the reservoir 203 and NO gas from the reservoir 204 are caused to flow into the mass flow controllers 207, 208 and 209 respectively by opening the valves 222, 223 and 224, controlling the pressure of each of the exit pressure gauges 227, 228 and 229 to 1 kg/cm 2 . Subsequently, the exit valves 217, 218 and 219, and the sub-valve are gradually opened to enter the raw material gases into the deposition chamber 201. In this case, the exit valves 217, 218 and 219 are adjusted so as to a desired value for the ratio among the SiH 4  gas, B 2  H 6  /H 2  gas and the NO gas. 
     The SiH 4  gas flow rate, the B 2  H 6  /H 2  gas flow rate and the NO gas flow rate, and the opening of the main valve 234 is adjusted while observing the reading on the vacuum gauge 236 so as to obtain a desired value for the pressure inside the deposition chamber 201. Then, after confirming that the temperature of the Al cylinder 237&#39; on the substrate holder 237 has been set by a heater 238 within a range from 50° to 350° C., a power source 240 is set to a predetermined electrical power to cause glow discharging in the deposition chamber 201 while controlling the above gas flow rates to thereby form a layer to be the first layer on the Al cylinder 237&#39;. 
     In the above case, it is possible to further improve the film forming speed by using appropriately selected raw material gases. For instance, in the case where Si 2  F 6  gas is used in stead of the SiH 4  gas, the film forming speed will be raised by some holds in comparison with the above case. 
     In order to form a layer to be the second layer on the already formed first layer, closing the exit valves 217 through 221, 244 and 247 opening the subvalves 232 and 233 and entirely opening the main valve 234 to evacuate the inside of the deposition chamber 201 and the gas pipings to be a high vacuum, B 2  H 6  /Ar gas, B 2  H 6  /He gas, NH 3  gas, an appropriate dopant imparting raw material gas and SiH 4  /He gas are fed into the deposition chamber 201 by operating the related valves in the same was as in the case of forming the first layer and the power source 240 is set to a predetermined electric power to cause glow discharging in the deposition chamber while controlling the flow rates of the raw material gases to thereby form the second layer. 
     In the case where the amount of hydrogen atom to be contained in the second layer is desired to be changed, it can be carried out by purposely adding H 2  gas to an appropiate raw material gas and by varying its flow rate as desired. 
     Further, in the case where hydrogen atom is desired to be introduced into the second layer, it can be carried out by feeding NF 3  gas together with an appropiate raw material gas into the deposition chamber 201. 
     All of the exit valves other than those required for upon forming the respective layers are of course closed. Further, upon forming the respective layers, the inside of the system is once evacuated to a high vacuum degree as required by closing the exit valves 217 through 221, 244 and 250 while opening the sub-valves 232 and 233 and fully opening the main valve 234 for avoiding that the gases having been used for forming the previous layer are left in the deposition chamber 201 and in the gas pipeways from the exit valves 217 through 221, 244 and 250 to the inside of the reaction chamber 201. 
     Further, during the film formation process for the respective layers, the substrate 237&#39; is rotated at a predetermined rotation speed by operating motor 239 in order to attain the uniformness fo the layer to be formed. 
     EXAMPLE 1 
     A light receiving member for use in electrophotography having a light receiving layer disposed on an Al cylinder having a mirror grinded surface was prepared under the layer forming conditions shown in Table 1 using the fabrication apparatus shown in FIG. 2. 
     And samples were provided by forming only a surface layer on an aluminum plate and on a Si-monocrystal wafer respectively placed on the substrate holder in the same manner for forming the surface layer in the above case using the same kind fabrication apparatus as shown in FIG. 2. 
     For the resulting light receiving member (hereinafter this kind light receiving member is referred to as &#34;drum&#34;), it was set with the conventional electrophotographic copying machine, and electrophotographic characteristics such as initial electrification efficiency (initial charging efficiency), residual voltage and appearance of a ghost were examined, then decrease in the electrification efficiency, deterioration on photosensitivity and increase of defective images after 1,500 thousand times repeated shots were respectively examined. 
     Further, the situation of an image flow on the drum under high temperature and high humidity atmosphere at 35° C. and 85% humidity was also examined. 
     In addition, the situation of breakdown voltage for the drum was observed by applying a high direct current voltage onto the drum. 
     Further, in addition, the abrasion resistance of the drum was examined by wearing its surface using a metallic needle having a round top while applying a predetermined load thereon. 
     The results obtained were as shown in Table 2. As Table 2 illustrates, superiorities in every evaluation item of the initial electrification efficiency (initial charging efficiency), defective image, surface abrasion, breakdown voltage and abrasion resistance for the drum were acknowledged. 
     As for the samples, the cordination number of boron nitride contained therein was examined in accordance with EXAFS (extended X-ray absorption fine structure ). As a result, it was found that tetrahedrally bonded boron nitrides were contained therein. 
     EXAMPLE 2 
     The procedures of Example 1 were repeated under the conditions shown in Table 3 wherein H 2  gas is additionally used in the formation of a surface layer to thereby obtain a drum and samples. The resultant drum and samples were evaluated by the same manners as in Example 1. 
     The results obtained were as shown in Table 4. 
     And as a result of examining a cordination number of boron nitride contained in the samples, it was aknowledged that tetrahedrally bonded boron nitrides were contained therein. 
     EXAMPLE 3 
     The procedures of Example 1 were repeated under the same conditions as shown in the foregoing Table 1, except that the vias voltage of the aluminum cylinder was controlled to -150V, to thereby obtain a drum and samples. The resultant drum and samples were evaluated by the same manners as in Example 1. 
     The results obtained were as shown in Table 5. As Table 5 illustrates, desirable results as those in Example 1 were acknowledged. As for the boron nitrides contained in the surface layer, it was acknowledged that they were tetrahedrally bonded boron nitrides. 
     EXAMPLE 4 
     A drum having a charge injection inhibition layer, a photoconductive layer and a surface layer on an aluminum cylinder was prepared under the conditions shown in Table 6 and following the procedures of Example 1. 
     The resultant drum was evaluated by the same manners as in Example 1. 
     The results obtained were as shown in Table 7. As Table 7 illustrates, superiorities in respective evaluation items were acknowledged for the drum. 
     EXAMPLE 5 
     An aluminum cylinder was subjected to anodic oxidation to form an aluminum oxide (Al 2  O 3  ) layer to be a charge injection inhibition layer thereon, and a photoconductive layer then a surface layer were continuously formed on the previously formed charge injection inhibition layer under the conditions shown in Table 8 following the procedures of Example 1 
     The resultant drum was evaluated by the same manners as in Example 1. The results obtained were as shown in Table 9. 
     As Table 9 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 6 
     A drum having an IR absorptive layer, a photoconductive layer and a surface laywr was prepared under the conditions shown in Table 10 and following the procedures of Example 1. The resultant drum was evoluted by the same manners as in Example 1. 
     In addition, the drum was set with the conventional electrophotographic copying machine using a semiconductor laser beam of 785 nm in wavelengths as the light source for image exposure in order to examine whether an infringe pattern appears or not on an image to be made. 
     The results obtained were as shown in Table 11. As Table 11 illustrates, superiorities in the respective evaluation items were acknowledged, and it was found that any infringe pattern did not appear on an image to be made. 
     EXAMPLE 7 
     A drum having a contact layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 12 and following the procedures of Example 1. 
     The resultant drum was evaluated by the same manners as in Example 1. The results obtained were as shown in Table 13. 
     As Table 13 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 8 
     A drum having an IR absorptive layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 14 and following the procedures of Example 1. The resultant drum was evaluated in the same way as in Example 6. The results obtained were as shown in Table 15. As Table 15 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 9 
     A drum having a contact layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 16 and following the procedures of Example 1. The resultant drum was evaluated in the same way as in Example 1. The results obtained were as shown in Table 17. 
     As Table 17 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 10 
     A drum having a contact layer, an IR absorptive layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 18 and following the procedures of Example 1. The resultant drum was evaluated in the same way as in Example 6. The results obtained were as shown in Table 19. As Table 19 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 11 
     The procedures of Example 1 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 20, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 12 
     The procedures of Example 2 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 21,to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 13 
     The procedures of Example 3 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 22, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 14 
     The procedures of Example 4 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 23, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 15 
     The procedures of Example 4 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 24  and Table 25, to thereby prepare multiple drums as shown in Table 26. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 16 
     The procedures of Example 4 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24, Table 27 and Table 28, to thereby prepare multiple drums as shown in Table 29. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 17 
     The procedures of Example 4 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24, Table 27 and Table 30, to thereby prepare multiple drums as shown in Table 31. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 18 
     The procedures of Example 5 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 25, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 19 
     The procedures of Example 5 were repeated, except that the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 28, to thereby prepare multiple drums as shown in Table 33. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 20 
     The procedures of Example 5 were repeated, except that the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 30, to thereby prepare multiple drums as shown in Table 34. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 21 
     The procedures of Example 6 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 36, to thereby prepare multiple drums as shown in Table 37. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 22 
     The procedures of Example 6 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38 and the photoconductive layer forming conditions were changed as shown in Table 25, to thereby prepare multiple drums as shown in Table 39. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 23 
     The procedures of Example 6 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, and the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 28, to thereby prepare multiple drums as shown in Table 40. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 24 
     The procedures of Example 6 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, and the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 30, to thereby prepare multiple drums as shown in Table 41. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 25 
     The procedures of Example 7 were repeated, except that the contact layer forming conditions were changed as shown in Table 42, to thereby prepare multiple drums as shown in Table 43. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 26 
     The procedures of Example 7 were repeated, except that the contact layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 44 and Table 25, to thereby prepare multiple drums as shown in Table 45. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 27 
     The procedures of Example 7 were repeated, except that the contact layer forming conditions, photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 44, Table 27 and Table 28, to thereby prepare multiple drums as shown in Table 46. 
     The resultant drums were evluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 28 
     The procedures of Example 4 were repeated, except that the contact layer forming conditions, photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 44, Table 27 and Table 30, to thereby prepare multiple drums as shown in Table 29. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 29 
     The procedures of Example 8 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 36, to thereby prepare multiple drums as shown in Table 48. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 30 
     The procedures of Example 8 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 49 and the IR absorptive layer forming conditions were changed as shown respectively in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 50. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 31 
     The procedures of Example 8 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51 and Table 28, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 52. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 32 
     The procedures of Example 8 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51 and Table 30, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 53. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 33 
     The procedures of Example 9 were repeated, except that the contact layer forming conditions were changed as shown in Table 44 and Table 54, to thereby prepare multiple drums as shown in Table 55. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 34 
     The procedures of Example 4 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 56, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 58. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 35 
     The procedures of Example 9 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24 and Table 28, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 59. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 36 
     The procedures of Example 9 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24 and Table 30, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 60. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 37 
     The procedures of Example 10 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 61, to thereby prepare multiple drums as shown in Table 62. 
     The resultant drums wre evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 38 
     The procedures of Example 4 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 64 and Table 63, to thereby prepare multiple drums as shown in Table 65. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 39 
     The procedures of Example 10 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 64, Table 66 and Table 28, to thereby prepare multiple drums as shown in Table 67. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 40 
     The procedures of Example 10 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 64, Table 66 and Table 30, to thereby prepare multiple drums as shown in Table 68. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 41 
     The procedures of Example 8 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 70, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 71. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 42 
     The procedures of Example 8 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 70, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 73. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 43 
     The procedures of Example 8 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 28, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 74. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 44 
     The procedures of Example 8 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 28, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 75. 
     The resultant drums wre evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 45 
     The procedures of Example 8 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 30, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 76. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 46 
     The procedures of Example 8 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 30, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 77. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 47 
     The procedures of Example 4 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 78 and the surface layer forming conditions were changed as shown in Table 79, to thereby prepare multiple drums as shown in Table 79. 
     The resultant drums were evaluated in the same way as in Example 1. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 48 
     The procedures of Example 8 were repeated, except that the IR absorptive layer forming conditions, the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 80 and the surface layer forming conditions were changed as shown in Table 81, to thereby prepare multiple drums as shown in Table 81. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 49 
     The procedures of Example 10 were repeated, except that the contact layer forming conditions, the IR absorptive layer forming conditions, the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 82 and the surface layer forming conditions wre changed as shown in Table 83, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 6. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 50 
     A drum having a charge injection inhibition layer, a photoconductive layer, an intermediate layer and a surface layer was prepared under the conditions shown in Table 84 and following the procedures of Example 1. 
     The resultant drum was evaluated in the same way as in Example 1, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 51 
     The mirror grinded cylinders were supplied for grinding process with cutting tool having various degrees. With the patterns of FIG. 3 and various cross section patterns as described in Table 85, multiple cylinders were provided. These cylinders were set to the fabrication apparatus of FIG. 2 accordingly, and used to prepare multiple drums under the same layer forming conditions of Example 1. The resulting drums were evaluated with the same procedures as in Example 1. 
     As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 52 
     The surface of mirror grinded cylinder was treated by dropping lots of bearing balls thereto to thereby form uneven shape composed of a plurality of fine dimples at the surface, and multiple cylinders having a cross section form of FIG. 4 and of a cross section pattern of Table 86 were provided. These cylinders were set to the fabrication apparatus of FIG. 2 accordingly and used for the preparation of multiple drums under the same layer forming conditions of Example 1. The resulting drums were evaluated with the same procedures of Example 1. 
     As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 53 
     A light receiving member for use in electrophotography having a light receiving layer disposed on Al cylinder having a mirror grinded surface was prepared under the layer forming conditions shown in Table 87 using the fabrication apparatus shown in FIG. 2. 
     And samples were provided by forming only a surface layer on an aluminum plate and on a Si-monocrystal wafer respectively placed on the substrate holder in the same manner for forming the surface layer in the above case using the same kind fabrication apparatus as shown in FIG. 2. 
     For the resulting light receiving member (hereinafter this kind light receiving member is referred to as &#34;drum&#34;), it was set with the conventional electrophotographic copying machine, and electrophotographic characteristics such as initial electrification efficiency (initial charging efficiency), residual voltage and appearance of a ghost were examined, then decrease in the electrification efficiency, the situation of surface abrasion and increase of defective image after 1,500 thousand times repeated shots were respecting examined. 
     Then, the situation of an image flow on the drum under high temperature and high humidity atmosphere at 35° C. and 85% humidity was also examined. 
     Further, the situation of superiority or inferiority in the cleaning property of the drum in accordance with the degree of background fogginess appearing on a blank image was examined by purposely replacing the original cleaning blade by another cleaning blade having a worn edge. 
     In addition, the situation of breakdown voltage for the drum was observed by applying a high direct current voltage onto the drum. 
     Further in addition, the abrasion resistance of the drum was examined by wearing its surface using a metallic needle having a round top while applying a predetermined load thereon. 
     The results obtained were as shown in Table 88. 
     As Table 88 illustrates, superiorities in the respective evaluation items, particularly of the items relative to defective image, image flow and cleaning property for the drum were acknowledged. 
     As for the samples, the cordination number of boron nitride contained therein was examined in accordance with EXAFS(extended X-ray absorption fine structure). As a result, it was found that there were contained tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state. 
     Then, as for the sample on the Si-monocrystal wafer, the residual stress was observed by making stripes of □/mm in checker form on its surface and by peeling off the adhesive tape adhered thereon. As a result, it was found that the sample excels in the residual stress. 
     EXAMPLE 54 
     The procedures of Example 53 were repeated under the conditions shown in Table 89 wherein H 2  gas is additionally used in the formation of a surface layer to therby obtain a drum and samples. The resultant drum and samples were evaluated by the same manners as in Example 53. 
     The results obtained were as shown in Table 90. As Table 90 illustrates, superiorities in the respective evaluation items were acknowleged. 
     And, as a result of examining a cordination number of boron nitride contained in the samples, it was found that there are contained tetrahedrally bonded boron nitride and trihedrelly bonded boron nitridde in mingled state. 
     EXAMPLE 55 
     The procedures of Example 53 were repeated under the same conditions as shown in the foregoing Table 87, except that the vias voltage of the aluminum cylinder was controlled to +100 V, to thereby obtain a drum and samples. The resultant drum and samples were evaluated by the same manners as in Example 53. 
     The results obtained were shown in Table 91. As Table 91 illustrates, desirable results as those in Example 53 were acknowledged. As for the situations of tetrahedrally bonded boron nitride and trihedrally bonded boron nitride and trihedrally bonded boron nitride in the samples, it was found that both of them are contained in mingled state. 
     EXAMPLE 56 
     A drum having a charge injection inhibition layer, a photoconductive layer and a surface layer on an alminum cylinder was prepared under the conditions shown in Table 92 and following the procedures of Example 53. 
     The resultant drum was evaluated by the same manners as in Example 53. 
     The results obtained were as shown in Table 93. As Table 93 illustrates, superiorities in respective evaluation items were acknowledged for the drum. 
     EXAMPLE 57 
     An alminum cylinder was subjected to anodic oxidation to form an aluminum oxide (Al 2  O 3 ) layer to be a charge injection inhibition layer thereon, and a photoconductive layer then a surface layer were continuously formed on the previously formed charge injection inhibition layer under the conditions shown in Table 44 following the procedures of Example 53. 
     The resultant drum was evaluated by the same manners as in Example 53. The results obtained were as shown in Table 95. 
     As Table 95 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 58 
     A drum having an IR absorptive layer, a photoconductive layer and a surface layer was prepared under the condition shown in Table 96 and following the procedures of Example 53. 
     In addition, the drum was set with the conventional electrophotographic copying machine using a semiconductor laser beam of 785 nm in wavelength as the light source for image exposure in order to examine whether an infringe pattern appears or not on an image to be made. 
     The results obtained were as shown in Table 97. As Table 97 illustrates, superiorities in the respective evaluation items were acknowledged, and it was found that any infringe pattern did not appear on an image to be made. 
     EXAMPLE 59 
     A drum having a contact layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 98 and following the procedures of Example 53. 
     The resultant drum was evaluated by the same manners as in Example 53. The results obtained were as shown in Table 99. 
     As Table 99 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 60 
     A drum having an IR absorptive layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 100 and following the procedures of Example 53. 
     The resultant drum was evaluated in the same way as in Example 58. The results obtained were as shown in Table 101. As Table 101 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 61 
     A drum having a contact layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 102 and following the procedures of Example 53. The resultant drum was evaluated in the same way as in Example 53. The results obtained were as shown in Table 103. 
     As Table 103 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 62 
     A drum having a contact layer, an IR absorptive layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 104 and following the procedures of Example 53. The resultant drum was evaluated in the same way as in Example 58. The results obtained were as shown in Table 105. As Table 105 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 63 
     The procedures of Example 53 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 20, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 64 
     The procedures of Example 54 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 21, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 65 
     The procedures of Example 55 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 22, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 66 
     The procedures of Example 56 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 23, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 67 
     The procedures of Example 56 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 24 and Table 25, to thereby prepare multiple drums as shown in Table 106. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 68 
     The procedures of Example 56 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24, Table 27 and Table 107, to thereby prepare multiple drums as shown in Table 108. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 69 
     The procedures of Example 56 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24, Table 27 and Table 109, to thereby prepare multiple drums as shown in Table 110. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 70 
     The procedures of Example 57 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 111, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 71 
     The procedures of Example 5 were repeated, except that the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 107, to thereby prepare multiple drums as shown in Table 112. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 72 
     The procedures of Example 57 were repeated, except that the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 109, to thereby prepare multiple drums as shown in Table 113. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 73 
     The procedures of Example 58 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 36, to thereby prepare multiple drums as shown in Table 114. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 74 
     The procedures of Example 58 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38 and the photoconductive layer forming conditions were changed as shown in Table 25, to thereby prepare multiple drums as shown in Table 115. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 75 
     The procedures of Example 58 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, and the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 107, to thereby prepare multiple drums as shown in Table 116. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 76 
     The procedures of Example 6 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, and the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 109, to thereby prepare multiple drums as shown in Table 117. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 77 
     The procedures of Example 59 were repeated, except that the contact layer forming conditions were changed as shown in Table 42, to thereby prepare multiple drums as shown in Table 118. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 78 
     The procedures of Example 59 were repeated, except that the contact layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 44 and Table 25, to thereby prepare multiple drums as shown in Table 119. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 79 
     The procedures of Example 59 were repeated, except that the contact layer forming conditions, photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 44, Table 27 and Table 107, to thereby prepare multiple drums as shown in Table 120. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 80 
     The procedures of Example 59 were repeated, except that the contact layer forming conditions, photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 44, Table 27 and Table 109, to thereby prepare multiple drums as shown in Table 121. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 81 
     The procedures of Example 60 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 36, to thereby prepare multiple drums as shown in Table 122. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 82 
     The procedures of Example 60 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 49 and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 153. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 83 
     The procedures of Example 60 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51 and Table 107, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 124. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 84 
     The procedures of Example 60 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51 and Table 125, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 125. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 85 
     The procedures of Example 61 were repeated, except that the contact layer forming conditions were changed as shown in Table 44 and Table 54, to thereby prepare multiple drums as shown in Table 126. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 86 
     The procedures of Example 61 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 56, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 127. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 87 
     The procedures of Example 61 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24 and Table 107, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 128. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 88 
     The procedures of Example 61 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24 and Table 109, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 129. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 89 
     The procedures of Example 62 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 61, to thereby prepare multiple drums as shown in Table 130. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 90 
     The procedures of Example 62 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 64 and Table 63, to thereby prepare multiple drums as shown in Table 131. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 91 
     The procedures of Example 62 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 64, Table 66 and Table 107, to thereby prepare multiple drums as shown in Table 132. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 92 
     The procedures of Example 62 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 64, Table 66 and Table 109, to thereby prepare multiple drums as shown in Table 133. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 93 
     The procedures of Example 60 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 134, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 135. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 94 
     The procedures of Example 60 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 134, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 136. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 95 
     The procedures of Example 60 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 107, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 137. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 96 
     The procedures of Example 60 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 107, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 138. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 97 
     The procedures of Example 60 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 109, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 139. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 98 
     The procedures of Example 60 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 109, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 140. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 99 
     The procedures of Example 56 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 78 and the surface layer forming conditions were changed as shown in Table 109, to thereby prepare multiple drums as shown in Table 141. 
     The resultant drums were evaluated in the same way as in Example 53. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 100 
     The procedures of Example 60 were repeated, except that the IR absorptive layer forming conditions, the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 80 and the surface layer forming conditions were changed as shown in Table 107, to thereby prepare multiple drums as shown in Table 142. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 101 
     The procedures of Example 62 were repeated, except that the contact layer forming conditions, the IR absorptive layer forming conditions, the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 82 and the surface layer forming conditions were changed as shown in Table 109, to thereby prepare multiple drums, as shown in Table 143. 
     The resultant drums were evaluated in the same way as in Example 58. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 102 
     A drum having a charge injection inhibition layer, a photoconductive layer, an intermediate layer and a surface layer was prepared under the conditions shown in Table 144 and following the procedures of Example 53. 
     The resultant drum was evaluated in the same way as in Example 53. As a result, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 103 
     The mirror grinded cylinders were supplied for grinding process with cutting tool having various degrees. With the patterns of FIG. 3 and various cross section patterns as described in Table 85, multiple cylinders were provided. These cylinders were set to the fabrication apparatus of FIG. 2 accordingly, and used to prepare multiple drums under the same layer forming conditions of Example 53. The resulting drums were evaluated with the same procedures as in Example 53. 
     As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 104 
     The surface of mirror grinded cylinder was treated by dropping lots of bearing balls thereto to thereby form uneven shape composed of a plurality of fine dimples at the surface, and multiple cylinders having a cross section form of FIG. 4 and of a cross section pattern of Table 86 were provided These cylinders were set to the fabrication apparatus of FIG. 2 accordingly and used for the preparation of multiple drums under the same layer forming conditions of Example 53. The resulting drums were evaluated with the same procedures of Example 53. 
     As a result, it was found that every drum is provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 105 
     A light receiving member for use in electrophotography having a light receiving layer disposed on an Al cylinder having a mirror grinded surface was prepared under the layer forming conditions shown in Table 145 using the fabrication apparatus shown in FIG. 2. 
     And samples were provided by forming only a surface layer comprising an upper layer and a lower layer on an aluminum plate and on a Si-monocrystal wafer respectively placed on the substrate holder in the same manner for forming the surface layer in the above case using the same kind fabrication apparatus as shown in FIG. 2. 
     For the resulting light receiving member (hereinafter this kind light receiving member is referred to as &#34;drum&#34;), it was set with the conventional electrophotographic copying machine, and electrophotographic characteristics such as initial electrification efficiency (initial charging efficiency), residual voltage and appearance of a ghost were examined, then decrease in the electrification efficiency, the situation of surface abrasion and increase of defective images after 1,500 thousand times repeated shots were respectively examined. 
     Then, the situation of an image flow of the drum under high temperature and high humidity atmosphere at 35° C. and 85% humidity was also examined. 
     Further, the situation of superiority or inferiority in the cleaning property of the drum in accordance with the degree of background fogginess appearity on a blank image was examined by purposely replacing the original cleaning blade by another cleaning blade having a worn edge. 
     In addition, the situation of breakdown voltage for the drum was observed by applying a high direct current voltage onto the drum. 
     Further in addition, the abrasion resistance of the drum was examined by wearing its surface using a metallic needle having a round top while applying a predetermined load thereon. 
     The results obtained were as shown in Table 146. As Table 146 illustrates, superiorities in the respective evaluation items, particularly of the items relative to defective image, image flow and cleaning property for the drum were acknowledged. 
     As for each of the samples, the cordination number of boron nitride contained in each of the upper and the lower layer was examined in accordance with EXAFS (extended X-ray absorption fine structure). As a result, it was found that there were contained tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state in the upper layer and there was contained tetrahedrally bonded boron nitride in the lower layer. 
     EXAMPLE 106 
     The procedures of Example 105 were repeated under the conditions shown in Table 147 wherein H 2  gas is additionally used in the formation of a surface layer to therby obtain a drum and samples. The resultant drum and samples were evaluated by the same manners as in Example 105. 
     The results obtained were as shown in Table 148. As Table 148 illustrates, superiorities in the respective evaluation items were acknowledged. 
     And as a result of examining the cordination number of boron nitride contained in each of the samples, it was found that there were contained tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state in the upper layer and there was contained tetrahedrally bonded boron nitride in the lower layer. 
     EXAMPLE 107 
     The procedures of Example 105 were repeated, except that the vias voltage of the cylinder in the case of forming a lower layer and the vias voltage in the case of forming an upper layer were controlled to be -150 V and +100 V respectively at the time of forming a surface layer, to thereby prepare a drum and samples. 
     The resultant drum and samples were evaluated by the same manners as in Example 105. 
     The results obtained were as shown in Table 149. As Table 149 illustrates, desirable results as those in Example 105 were acknowledged. 
     As for the situations of tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in each of the samples, it was found that there were contained trihedrally bonded boron nitride and tetrahedrally bonded boron nitride in mingled state in the upper layer and there was contained tetrahedrally bonded boron nitride in the lower layer. 
     EXAMPLE 108 
     A drum having a charge injection inhibition layer, a photoconductive layer and a surface layer on an alminum cylinder was prepared under the conditions shown in Table 150 and following the procedures of Example 105. 
     The resultant drum was evaluated by the same manners as in Example 105. 
     The results obtained were as shown in Table 151. As Table 151 illustrates, superiorities in respective evaluation items were acknowledged for the drum. 
     EXAMPLE 109 
     An alminum cylinder was subjected to anodic oxidation to form an aluminum oxide (Al 2  O 3 ) layer to be a charge injection inhibition layer thereon, and a photoconductive layer then a surface layer were continuously formed on the previously formed charge injection inhibition layer under the conditions shown in Table 152 following the procedures of Example 105. 
     The resultant drum was evaluated by the same manners as in Example105. The results obtained were as shown in Table 153. 
     As Table 153 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 110 
     A drum having an IR absorptive layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 154 and following the procedures of Example 105. 
     The resultant drum was evaluated by the same manners as in Example 105. 
     In addition, the drum was set with the conventional electrophotographic copying machine using a semiconductor laser beam of 785 nm in wavelength as the light source for image exposure in order to examine whether an infringe pattern appears or not on an image to be made. 
     The results obtained were as shown in Table 155. As Table 155 illustrates, superiorities in the respective evaluation items were acknowledged, and it was found that any infringe pattern did not appear on an image to be made. 
     EXAMPLE 111 
     A drum having a contact layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 156 and following the procedures of Example 105. 
     The resultant drum was evaluated by the same manners as in Example 105. The results obtained were as shown in Table 157. 
     As Table 157 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 112 
     A drum having an IR absorptive layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 158 and following the procedures of Example 105. The resultant drum was evaluated in the same way as in Example 110. The results obtained were as shown in Table 159. As Table 159 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 113 
     A drum having a contact layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 160 and following the procedures of Example 105. The resultant drum was evaluated in the same way as in Example 105. The results obtained were as shown in Table 161. 
     As Table 161 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 114 
     A drum having a contact layer, an IR absorptive layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 162 and following the procedures of Example 105. The resultant drum was evaluated in the same way as in Example 110. The results obtained were as shown in Table 163. As Table 163 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 115 
     The procedures of Example 105 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 20, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 116 
     The procedures of Example 106 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 21, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 117 
     The procedures of Example 107 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 22, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 118 
     The procedures of Example 108 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 23, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 119 
     The procedures of Example 108 were repeated, except that the charge injection inhibiton layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 24 and Table 25, to thereby prepare multiple drums as shown in Table 164. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 120 
     The procedures of Example 108 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24, Table 27 and Table 165, to thereby prepare multiple drums as shown in Table 166. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 121 
     The procedures of Example 108 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24, Table 27 and Table 167, to thereby prepare multiple drums as shown in Table 168. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 122 
     The procedures of Example 109 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 25, to thereby prepare multiple drums as shown in Table 169. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 123 
     The procedure of Example 109 were repeated, except that the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 165, to thereby prepare multiple drums as shown in Table 170. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 124 
     The procedures of Example 109 were repeated, except that the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 167, to thereby prepare multiple drums as shown in Table 171. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 125 
     The procedures of Example 110 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 36, to thereby prepare multiple drums as shown in Table 172. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 126 
     The procedures of Example 110 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38 and the photoconductive layer forming conditions were changed as shown in Table 25, to thereby prepare multiple drums as shown in Table 173. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 127 
     The procedures of Example 110 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, and the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 165, to thereby prepare multiple drums as shown in Table 174. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 128 
     The procedures of Example 110 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, and the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 167, to thereby prepare multiple drums as shown in Table 175. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 129 
     The procedures of Example 111 were repeated, except that the contact layer forming conditions were changed as shown in Table 42, to thereby prepare multiple drums as shown in Table 176. 
     The resulant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 130 
     The procedures of Example 111 were repeated, except that the contact layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 44 and Table 25, to thereby prepare multiple drums as shown in Table 177. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 131 
     The procedures of Example 111 were repeated, except that the contact layer forming conditions, photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 44, Table 27 and Table 165, to thereby prepare multiple drums as shown in Table 178. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 132 
     The procedures of Example 111 were repeated, except that the contact layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 44, Table 27 and Table 167, to thereby prepare multiple drums as shown in Table 179. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 133 
     The procedures of Example 112 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 36, to thereby prepare multiple drums as shown in Table 180. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 134 
     The procedures of Example 112 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 49 and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 181. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 135 
     The procedures of Example 112 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51 and Table 165, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 182. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 136 
     The procedures of Example 112 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51 and Table 167, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 183. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 137 
     The procedures of Example 113 were repeated, except that the contact layer forming conditions were changed as shown in Table 44 and Table 54, to thereby prepare multiple drums as shown in Table 184. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 138 
     The procedures of Example 113 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 56, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 185. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 139 
     The procedures of Example 113 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24 and Table 165, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 186. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 140 
     The procedures of Example 113 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24 and Table 167, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 187. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 141 
     The procedures of Example 114 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 61, to thereby prepare multiple drums as shown in Table 188. The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 142 
     The procedures of Example 114 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 64 and Table 63, to thereby prepare multiple drums as shown in Table 189. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 143 
     The procedures of Example 114 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 64, Table 66 and Table 165, to thereby prepare multiple drums as shown in Table 190. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 144 
     The procedures of Example 114 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 64, Table 66 and Table 167, to thereby prepare multiple drums as shown in Table 191. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 145 
     The procedures of Example 112 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51. Table 69 and Table 192, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 193. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 146 
     The procedures of Example 112 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 192, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 194. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 147 
     The procedures of Example 112 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 165, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 195. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 148 
     The procedures of Example 112 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 165, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 196. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 149 
     The procedures of Example 112 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 167, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 197. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 150 
     The procedures of Example 112 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 167, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 198. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 151 
     The procedures of Example 108 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 78 and the surface layer forming conditions were changed as shown in Table 167, to thereby prepare multiple drums as shown in Table 199. 
     The resultant drums were evaluated in the same way as in Example 105. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 152 
     The procedures of Example 112 were repeated, except that the IR absorptive layer forming conditions, the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 80 and the surface layer forming conditions were changed as shown in Table 167, to thereby prepare multiple drums as shown in Table 200. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 153 
     The procedures of Example 114 were repeated, except that the contact layer forming conditions, the IR absorptive layer forming conditions, the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 82 and the surface layer forming conditions were changed as shown in Table 167, to thereby prepare multiple drums as shown in Table 201. 
     The resultant drums were evaluated in the same way as in Example 110. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 154 
     A drum having a charge injection inhibition layer, a photoconductive layer, an intermediate layer and a surface layer was prepared under the conditions shown in Table 202 and following the procedures of Example 105. 
     The resultant drum was evaluated in the same way as in Example 105. As a result, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 155 
     The mirror grinded cylinders were supplied for grinding process with cutting tool having various degrees. With the patterns of FIG. 3 and various cross section patterns as described in Table 85, multiple cylinders were provided. These cylinders were set to the fabrication apparatus of FIG. 2 accordingly, and used to prepare multiple drums under the same layer forming conditions of Example 105. The resulting drums were evaluated with the same procedures as in Example 105. 
     As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 156 
     The surface of mirror grinded cylinder was treated by dropping lots of bearing balls thereto to thereby form uneven shape composed of a plurality of fine dimples at the surface, and multiple cylinders having a cross section form of FIG. 4 and of a cross section pattern of Table 86 were provided These cylinders were set to the fabrication apparatus of FIG. 2 accordingly and used for the preparation of multiple drums under the same layer forming conditions of Example 105. The resulting drums were evaluated with the same procedures of Example 105. 
     As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 157 
     A light receiving member for use in electrophotography having a light receiving layer disposed on an A1 cylinder having a mirror grinded surface was prepared under the layer forming conditions shown in Table 203(a) and Table 203(b) using the fabrication apparatus shown in FIG. 2. 
     And samples were provided by forming only a surface layer on an aluminum plate and on a Si-monocrystal wafer respectively placed on the substrate holder in the same manner for forming the surface layer in the above case using the same kind fabrication apparatus as shown in FIG. 2. 
     For the resulting light receiving member (hereinafter this kind light receiving member is referred to as &#34;drum&#34;), it was set with the conventional electrophotographic copying machine, and electrophotographic characteristics such as initial electrification efficiency (initial charging efficiency), residual voltage and appearance of a ghost were examined, then decrease in the electrification efficiency, the situation of surface abrasion and increase of defective images after 1,500 thousand times repeated shots were respectively examined. 
     Then, the situation of an image flow on the drum under high temperature and high humidity atmosphere at 35° C. and 85% humidity was also examined. 
     Further, the situation of superiority or inferiority in the cleaning property of the drum in accordance with the degree of background fogginess appearing on a blank image was examined by purposely replacing the original cleaning blade by another cleaning blade having a worn edge. 
     In addition, the situation of breakdown voltage for the drum was observed by applying a high direct current voltage onto the drum. 
     Further in addition, the abrasion resistance of the drum was examined by wearing its surface using a metallic needle having a round top while applying a predetermined load thereon. 
     The results obtained were as shown in Table 204. As Table 204 illustrates, extreme superiorities in every evaluation item of the initial electrification efficiency (initial charging efficiency), defective image, surface abrasion, breakdown voltage and abrasion resistance for the drum were acknowledged. 
     As for each of the samples, the cordination number of boron nitride contained therein was examined in accordance with EXAFS (extended X-ray absorption fine structure). As a result, it was found that every sample contained tetrahedrally bonded boron nitride. 
     EXAMPLE 158 
     The procedures of Example 157 were repeated under the conditions shown in Table 205(a) and Table 205(b) wherein H 2  gas is additionally used in the formation of a surface layer to thereby obtain a drum and samples. The resultant drum and samples were evaluated by the same manners as in Example 157. 
     The results obtained were as shown in Table 206. As Table 206 illustrates, superiorities in the respective evaluation items were acknowledged for the drum. 
     And, as for each of the samples, it was found that every sample contained tetrahedrally bonded boron nitride. 
     EXAMPLE 159 
     The procedures of Example 157 were repeated under the same conditions as shown in the foregoing Table 203(a) and Table 203(b), except that the vias voltage of the aluminum cylinder was controlled to -150 V, to thereby obtain a drum and samples. The resultant drum and samples were evaluated by the same manners as in Example 157. 
     The results obtained were shown in Table 207. As Table 207 illustrated, desirable results as those in Example 157 were acknowledged. As for the boron nitrides contained in the surface layer, it was acknowledged that every sample contained tetrahedrally bonded boron nitride. 
     EXAMPLE 160 
     A drum having a charge injection inhibition layer, a photoconductive layer and a surface layer on an aluminum cylinder was prepared under the conditions shown in Table 208(a) and Table 208(b) and following the procedures of Example 157. 
     The resultant drum was evaluated by the same manners a s in Example 157. The results obtained were as shown in Table 7. As Table 7 illustrates, superiorities in the respective evaluation items were acknowledged for the drum. 
     EXAMPLE 161 
     An aluminum cylinder was subjected to anodic oxidation to form an aluminum oxide (Al 2  O 3 ) layer to be a charge injection inhibition layer thereon, and a photoconductive layer then a surface layer were continuously formed on the previously formed charge injection inhibition layer under the conditions shown in Table 210(a) and Table 210(b) following the procedures of Example 157. 
     The resultant drum was evaluated by the same manners as in Example 157. The results obtained were as shown in Table 211. 
     As Table 211 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 162 
     A drum having an IR absorptive layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 212(a) and Table 212(b) and following the procedures of Example 157. 
     In addition, the drum was set with the conventional electrophotographic copying machine using a semiconductor laser beam of 785 nm in wavelength as the light source for image exposure in order to examine whether an infringe pattern appears or not on an image to be made. 
     The results obtained were as shown in Table 213. As Table 213 illustrates, superiorities in the respective evaluation items were acknowledged, and it was found that any infringe pattern did not appear on an image to be made. 
     EXAMPLE 163 
     A drum having a contact layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 214(a) and Table 214(b) and following the procedures of Example 157. 
     The resultant drum was evaluated by the same manners as in Example 157. The results obtained were as shown in Table 215. 
     As Table 215 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 164 
     A drum having an IR absorptive layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 216(a) and Table 216(b) and following the procedures of Example 157. The resultant drum was evaluated in the same way as in Example 162. The results obtained were as shown in Table 217. As Table 217 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 165 
     A drum having a contact layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 218(a) and Table 218(b) and following the procedures of Example 157. The resultant drum was evaluated in the same way as in Example 157. The results obtained were as shown in Table 219. 
     As Table 219 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 166 
     A drum having a contact layer, an IR absorptive layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 220(a) and Table 220(b) and following the procedures of Example 157. The resultant drum was evaluated in the same way as in Example 162. The results obtained were as shown in Table 221. As Table 221 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 167 
     The procedures of Example 157 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 222, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 168 
     The procedures of Example 158 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 223, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 169 
     The procedures of Example 159 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 224, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 170 
     The procedures of Example 160 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 225, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 171 
     The procedures of Example 160 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 24 and Table 25, to thereby prepare multiple drums as shown in Table 226. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 172 
     The procedures of Example 160 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24, Table 27 and Table 227, to thereby prepare multiple drums as shown in Table 228. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 173 
     The procedures of Example 160 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24, Table 27 and Table 229, to thereby prepare multiple drums as shown in Table 230. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 174 
     The procedures of Example 161 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 25, to thereby prepare multiple drums as shown in Table 231. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 175 
     The procedures of Example 161 were repeated, except that the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 227, to thereby prepare multiple drums as shown in Table 232. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 176 
     The procedures of Example 161 were repeated, except that the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 229, to thereby prepare multiple drums as shown in Table 233. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 177 
     The procedures of Example 162 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 36, to thereby prepare multiple drums as shown in Table 234. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 178 
     The procedures of Example 162 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38 and the photoconductive layer forming conditions were changed as shown in Table 25, to thereby prepare multiple drums as shown in Table 235. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 179 
     The procedures of Example 162 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, and the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 227, to thereby prepare multiple drums as shown in Table 236. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 180 
     The procedures of Example 162 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38 and the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 229, to thereby prepare multiple drums as shown in Table 237. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 181 
     The procedures of Example 163 were repeated, except that the contact layer forming conditions were changed as shown in Table 163, to thereby prepare multiple drums as shown in Table 238. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 182 
     The procedures of Example 163 were repeated, except that the contact layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 44 and Table 25, to thereby prepare multiple drums as shown in Table 239. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 183 
     The procedures of Example 163 were repeated, except that the contact layer forming conditions, photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 44. Table 27 and Table 277, to thereby prepare multiple drums as shown in Table 240. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 184 
     The procedures of Example 163 were repeated, except that the contact layer forming conditions, photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 44,  Table 27 and Table 279, to thereby prepare multiple drums as shown in Table 241. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 185 
     The procedures of Example 164 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 36, to thereby prepare multiple drums as shown in Table 242. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 186 
     The procedures of Example 164 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 49 and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 243. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 187 
     The procedures of Example 164 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51 and Table 227, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 244. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 188 
     The procedures of Example 164 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51 and Table 229, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 245. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 189 
     The procedures of Example 165 were repeated, except that the contact layer forming conditions were changed as shown in Table 44 and Table 54, to thereby prepare multiple drums as shown in Table 246. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 190 
     The procedures of Example 165 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 56, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 247. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 191 
     The procedures of Example 165 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24 and Table 227, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 248. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 192 
     The procedures of Example 165 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24 and Table 229, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 249. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 193 
     The procedures of Example 166 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 61, to thereby prepare multiple drums as shown in Table 250. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 194 
     The procedures of Example 166 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 64 and Table 63, to thereby prepare multiple drums as shown in Table 251. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 195 
     The procedures of Example 166 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 64, Table 66 and Table 227, to thereby prepare multiple drums as shown in Table 252. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 196 
     The procedures of Example 166 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 64, Table 66 and Table 229, to thereby prepare multiple drums as shown in Table 253. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 197 
     The procedures of Example 164 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 254, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 255. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 198 
     The procedure of Example 164 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 254, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 256. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 199 
     The procedures of Example 164 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 227, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 257. 
     The resultant drums were evauated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 200 
     The procedures of Example 164 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 227, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 258. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 201 
     The procedures of Example 164 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 229, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 259. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 202 
     The procedures of Example 164 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 229, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 260. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 203 
     The procedures of Example 160 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 78 and the surface layer forming conditions were changed as shown in Table 227, to thereby prepare multiple drums as shown in Table 261. 
     The resultant drums were evaluated in the same way as in Example 157. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 204 
     The procedures of Example 164 were repeated, except that the IR absorptive layer forming conditions, the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 80 and the surface layer forming conditions were changed as shown in Table 229, to thereby prepare multiple drums as shown in Table 262. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 205 
     The procedures of Example 166 were repeated, except that the contact layer forming conditions, the IR absorptive layer forming conditions, the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 82 and the surface layer forming conditions were changed as shown in Table 229, to thereby prepare multiple drums as shown in Table 263. 
     The resultant drums were evaluated in the same way as in Example 162. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 206 
     A drum having a charge injection inhibition layer, a photoconductive layer, an intermediate layer and a surface layer was prepared under the conditions shown in Table 264 and following the procedures of Example 157. 
     The resultant drum was evaluated in the same way as in Example 157, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 207 
     The mirror grinded cylinders were supplied for grinding process with cutting tool having various degrees. With the patterns of FIG. 3 and various cross section patterns as described in Table 85, multiple cylinders were provided. These cylinders were set to the fabrication apparatus of FIG. 2 accordingly, and used to prepare multiple drums under the same layer forming conditions of Example 157. The resulting drums were evaluated with the same procedures as in Example 157. 
     As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 208 
     The surface of mirror grinded cylinder was treated by dropping lots of bearing balls thereto to thereby form uneven shape composed of a plurality of fine dimples at the surface, and multiple cylinders having a cross section form of FIG. 4 and a cross section pattern of Table 86 were provided. These cylinders were set to the fabrication apparatus of FIG. 2 accordingly and used for the preparation of multiple drums under the same layer forming conditions of Example 157. The resulting drums were evaluated with the same procedures of Example 157. 
     As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 209 
     A light receiving member for use in electrophotography having a light receiving layer disposed on an Al cylinder having a mirror grinded surface was prepared under the layer forming conditions shown in Table 265(a) and Table 265(b) using the fabrication apparatus shown in FIG. 2. 
     And samples were provided by forming only a surface layer on an aluminum plate and on a Si-monocrystal wafer respectively placed on the substrate holder in the same manner for forming the surface layer in the above case using the same kind fabrication apparatus as shown in FIG. 2. 
     For the resulting light receiving member (hereinafter this kind light receiving member is referred to as &#34;drum&#34;), it was set with the conventional electrophotographic copying machine, and electrophotographic characteristics such as initial electrification efficiency (initial charging efficiency), residual voltage and appearance of a ghost were examined, then decrease in the electrification efficiency, the situation of surface abrasion and increase of defective images after 1,500 thousand times repeated shots were respectively examined. 
     Then, the situation of an image flow on the drum under high temperature and high humidity atmosphere at 35° C. and 85% humidity was also examined. 
     Further, the situation of superiority or inferiority in the cleaning property of the drum in accordance with the degree of background fogginess appearing on a blank image was examined by purposely replacing the original cleaning blade by another cleaning blade having a worm edge. 
     In addition, the situation of breakdown voltage for the drum was observed by applying a high direct current voltage onto the drum. 
     Further in addition, the abrasion resistance of the drum was examined by wearing its surface using a metallic needle having a round top while applying a predetermined load thereon. 
     The results obtained were as shown in Table 266. As Table 266 illustrates, superiorities in the respective evaluation items, particularly of the items relative to defective image, image flow and cleaning property for the drum were acknowledged. 
     As for the samples, the cordination number of boron nitride contained therein was examined in accordance with EXAFS (extended X-ray absorption fine structure). As a result, it was found that there were contained tetrahedrally bonded boron nitrides and trihedrally bonded boron nitride in mingled state. 
     Then, as for the sample on the si-monocrystal wafer, the residual stress was observed by making stripes of □/mm in checker from on its surface and by peeling off the adhesive tape adhered thereon. As a result, it was found that the sample exceled in the residual stress. 
     EXAMPLE 210 
     The procedures of Example 209 were repeated under the conditions shown in Table 267(a) and Table 276(b) wherein H 2  gas is additionally used in the formation of a surface layer, to therby obtain a drum and samples. The resultant drum and samples were evaluated by the same manners as in Example 209. 
     The results obtained were as shown in Table 268. As Table 268 illustrates, superiorities in the respective evaluation items were acknowledged. 
     And as a result of examining the cordination number of boron nitride contained in each of the samples, it was found that there were contained tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state. 
     EXAMPLE 211 
     The procedures of Example 209 were repeated under the same conditions as shown in the foregoing Table 265(a) and Table 265(b), except that the vias voltage of the aluminum cylinder was controlled to +100 V, to thereby obtain a drum and samples. The resultant drum and samples were evaluated by the same manners as in Example 209. 
     The results obtained were as shown in Table 269. As Table 269 illustrates, desirable results as those in Example 209 were acknowledged. As for the situations of tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in each of the samples. It was found that both of them were contained in mingled state. 
     EXAMPLE 212 
     A drum having a charge injection inhibition layer, a photoconductive layer and a surface layer on an aluminum cylinder was prepared under the conditions shown in Table 270(a) and Table 270(b) and following the procedures of Example 209. 
     The resultant drum was evaluated by the same manners as in Example 209. 
     The results obtained were as shown in Table 271. As Table 271 illustrates, superiorities in respective evaluation items were acknowledged for the drum. 
     EXAMPLE 213 
     An aluminum cylinder was subjected to anodic oxidation to form an aluminium oxide (Al 2  O 3 ) layer to be a charge injection inhibition layer thereon, and a photoconductive layer then a surface layer were continuously formed on the previously formed charge injection inhibition layer under the conditions shown in Table 272(a) and Table 272(b) following the procedures of Example 209. 
     The resultant drum was evaluated by the same manners as in Example 209. The results obtained were as shown in Table 273. 
     As Table 273 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 214 
     A drum having an IR absorptive layer, a photoconductive layer and a surface layer was prepared under the condition shown in Table 274(a) and Table 274(b) and following the procedures of Example 209. 
     In addition, the drum was set with the conventional electrophotographic copying machine using a semiconductor laser beam of 785 nm in wavelength as the light source for image exposure in order to examine whether an infringe pattern appears or not on an image to be made. 
     The results obtained were as shown in Table 275. As Table 275 illustrates, superiorities in the respective evaluation items were acknowledged, and it was found that many infringe pattern did not appear on an image to be made. 
     EXAMPLE 215 
     A drum having a contact layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 276(a) and Table 276(b) and following the procedures of Example 209. 
     The resultant drum was evaluated by the same manners as in Example 209. The results obtained were as shown in Table 277. 
     As Table 277 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 216 
     A drum having an IR absorptive layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 278(a) and Table 278(b) and following the procedures of Example 209. The resultant drum was evaluated in the same way as in Example 214. The results obtained were as shown in Table 279. As Table 279 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 217 
     A drum having a contact layer, a charge injection inhibition layer, a photoconductive layer and a surface  layer was prepared under the conditions shown in Table 280(a) and Table 280(b) and following the procedures of Example 209. The resultant drum was evaluated in the same way as in Example 209. The results obtained were as shown in Table 281. 
     As Table 281 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 218 
     A drum having a contact layer, an IR absorptive layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 282(a) and Table 282(b) and following the procedures of Example 209. The resultant drum was evaluated in the same way as in Example 214. The results obtained were as shown in Table 283. As Table 283 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 219 
     The procedures of Example 209 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 284, to thereby prepare multiple drum. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 220 
     The procedures of Example 210 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 285, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 221 
     The procedures of Example 211 was repeated, except that the photoconductive layer forming conditions were changed as shown in Table 286, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotograhic characteristics. 
     EXAMPLE 222 
     The procedures of Example 212 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 287, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 223 
     The procedures of Example 212 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 24 and Table 25, to thereby prepare multiple drums as shown in Table 288. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 224 
     The procedures of Example 212 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24, Table 27 and Table 289,  to thereby prepare multiple drums as shown in Table 290. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 225 
     The procedures of Example 212 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24, Table 27 and Table 291, to thereby prepare multiple drums as shown in Table 292. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 226 
     The procedures of Example 213 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 25, to thereby prepare multiple drums as shown in Table 293. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 227 
     The procedures of Example 213 were repeated, except that the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 289, to thereby prepare multiple drums as shown in Table 294. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 228 
     The procedures of Example 213 were repeated, except that the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 291, to thereby prepare multiple drums as shown in Table 295. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 229 
     The procedures of Example 214 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 36, to thereby prepare multiple drums as shown in Table 296. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 230 
     The procedures of Example 214 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38 and the photoconductive layer forming conditions were changed as shown in Table 25, to thereby prepare multiple drums as shown in Table 297. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 231 
     The procedures of Example 214 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, and the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 289, to thereby prepare multiple drums as shown in Table 298. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 232 
     The procedures of Example 214 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, and the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 291. to thereby prepare multiple drums as shown in Table 299. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 233 
     The procedures of Example 215 were repeated, except that the contact layer forming conditions were changed as shown in Table 42, to thereby prepare multiple drums as shown in Table 300. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 234 
     The procedures of Example 215 were repeated, except that the contact layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 44 and Table 25, to thereby prepare multiple drums as shown in Table 301. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 235 
     The procedures of Example 215 were repeated, except that the contact layer forming conditions, photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 44, Table 27 and Table 289, to thereby prepare multiple drums as shown in Table 302. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electophotographic characteristics. 
     EXAMPLE 236 
     The procedures of Example 215 were repeated except that the contact layer forming conditions, photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 44, Table 27 and Table 291, to thereby prepare multiple drums as shown in Table 303. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 237 
     The procedures of Example 216 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 36, to thereby prepare multiple drums as shown in Table 304. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 238 
     The procedures of Example 216 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 49 and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 305. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 239 
     The procedures of Example 216 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51 and Table 289, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 306. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 240 
     The procedures of Example 216 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51 and Table 291, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 307. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 241 
     The procedures of Example 217 were repeated, except that the contact layer forming conditions were changed as shown in Table 44 and Table 54, to thereby prepare multiple drums as shown in Table 308. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 242 
     The procedures of Example 217 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 56, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 309. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 243 
     The procedures of Example 217 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24 and Table 289, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 310. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 244 
     The procedures of Example 217 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24 and Table 30, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 311. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 245 
     The procedures of Example 218 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 61, to thereby prepare multiple drums as shown in Table 312. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 246 
     The procedures of Example 218 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 64 and Table 63, to thereby prepare multiple drums as shown in Table 313. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 247 
     The procedures of Example 218 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 64, Table 66 and Table 281, to thereby prepare multiple drums as shown in Table 314. The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 248 
     The procedures of Example 218 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 64, Table 66 and Table 291, to thereby prepare multiple drums as shown in Table 315. The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 249 
     The procedures of Example 216 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 316, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 317. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 250 
     The procedures of Example 216 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 316, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 318. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 251 
     The procedures of Example 216 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 289, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 319. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 252 
     The procedures of Example 216 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 289, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 320. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 253 
     The procedures of Example 216 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 291, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 321. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 254 
     The procedures of Example 216 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 291, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 322. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 255 
     The procedures of Example 212 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 78 and the surface layer forming conditions were changed as shown in Table 291, to thereby prepare multiple drums as shown in Table 323. 
     The resultant drums were evaluated in the same way as in Example 209. As a result, it was found that every drum was provided with practically applicable desired electophotographic characteristics. 
     EXAMPLE 256 
     The procedures of Example 216 were repeated, except that the IR absorptive layer forming conditions, the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 80 and the surface layer forming conditions were changed as shown in Table 291, to thereby prepare multiple drums as shown in Table 324. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 257 
     The procedures of Example 218 were repeated, except that the contact layer forming conditions, the IR absorptive layer forming conditions, the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 82 and the surface layer forming conditions were changed as shown in Table 291, to thereby prepare multiple drums as shown in Table 325. 
     The resultant drums were evaluated in the same way as in Example 214. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 258 
     A drum having a charge injection inhibition layer, a photoconductive layer, an intermediate layer and a surface layer was prepared under the conditions shown in Table 326 and following the procedures of Example 209. 
     The resultant drum was evaluated in the same way as in Example 209, As a result superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 259 
     The mirror grinded cylinders were supplied for grinding process with cutting tool having various degrees. With the patterns of FIG. 3 and various cross section patterns as described in Table 85, multiple cylinders were provided. These cylinders were set to the fabrication apparatus of FIG. 2 accordingly, and used to prepare multiple drums under the same layer forming conditions of Example 209. The resulting drums were evaluated with the same procedures as in Example 209. 
     As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 260 
     The surface of mirror grinded cylinder was treated by dropping lots of bearing balls thereto to thereby form uneven shape composed of a plurality of fine dimples at the surface, and multiple cylinders having a cross section form of FIG. 4 and of a cross section pattern of Table 86 were provided. These cylinders were set to the fabrication apparatus of FIG. 2 accordingly and used for the preparation of multiple drums under the same layer forming conditions of Example 209. The resulting drums were evaluated with the same procedures of Example 209. 
     As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 261 
     A light receiving member for use in electrophotography having a light receiving layer disposed on an A1 cylinder having a mirror grinded surface was prepared under the layer forming conditions shown in Table 327(a) and Table 327(b) using the fabrication apparatus shown in FIG. 2. 
     And samples were provided by forming only a surface layer comprising an upper layer and a lower layer on the aluminum plate and on a Si-monocrystal wafer respectively placed on the substrate holder in the same manner for forming the surface layer in the above case using the same kind fabrication apparatus as shown in FIG. 2. 
     For the resulting light receiving member (hereinafter this kind light receiving member is referred to as &#34;drum&#34;), it was set with the conventional electrophotographic copying machine, and electrophotographic characteristics such as initial electrification efficiency (initial charging efficiency), residual voltage and appearance of a ghost were examined, then decrease in the electrification efficiency, the situation of surface abration and increase of defective images after 1,500 thousand times repeated shots were respectively examined. 
     Then, the situation of an image flow on the drum under high temperature and high humidity atmosphere at 35° C. and 85% humidity was also examined. 
     Further, the situation of superiority or inferiority in the cleaning property of the drum in accordance with the degree of background fogginess appearing on a blank image was examined by purposely replacing the original cleaning blade by another cleaning blade having a worn edge. 
     In addition, the situation of breakdown voltage for the drum was observed by applying a high direct current voltage onto the drum. 
     Further in addition, the abrasion resistance of the drum was examined by wearing its surface using a metallic needle having a round top while applying a predetermined load thereon. 
     The results obtained were as shown in Table 328. As Table 328 illustrates, superiorities in the respective evaluation items, particularly of the items relative to defective image, image flow abrasion registance, breakdown voltage and cleaning property for the drum were acknowledged. 
     As for each of the samples, the cordination number of boron nitride contained in each of the upper layer and the lower layer was examined in accordance with EXAFS (extended X-ray absorption fine structure). As a result, it was found that there were contained tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state in the upper layer and there was contained tetrahedrally bonded boron nitride in the lower layer. 
     EXAMPLE 262 
     The procedures of Example 261 were repeated under the conditions shown in Table 329(a) and Table 329(b) wherein H 2  gas is additionally used in the formation of a surface layer to thereby obtain a drum and samples. The resultant drum and samples were evaluated by the same manners as in Example 261. 
     The results obtained were as shown in Table 330. As Table 330 illustrates, superiorities in the respective evaluation items were acknowledged. 
     And as a result of examining a cordination number of boron nitride contained in each of the samples, it was found that there were contained tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in mingled state in the upper layer and there was contained tetrahedrally bonded boron nitride in the lower layer. 
     EXAMPLE 263 
     The procedures of Example 261 were repeated, except that the vias voltage of the cylinder in the case of forming a lower layer and the vias voltage in the case of forming an upper layer were controlled to be -150 V and +100 V respectively at the time of forming a surface layer, to thereby prepare a drum and samples. 
     The resultant drum and samples were evaluated by the same manners as in Example 261. 
     The results obtained were shown in Table 331. As Table 331 illustrates, desirable results as those in Example 261 were acknowledged. As for the situation of tetrahedrally bonded boron nitride and trihedrally bonded boron nitride in each of the samples, it was found that there were contained trihedrally bonded boron nitride and tetrahedrally bonded boron nitride in mingled state in the upper layer and there was contained tetrahedrally bonded boron nitride in the lower layer. 
     EXAMPLE 264 
     A drum having a charge injection inhibition layer, a photoconductive layer and a surface layer on an aluminum cylinder was prepared under the conditions shown in Table 332(a) and Table 332(b) and following the procedures of Example 261. 
     The resultant drum was evaluated by the same manners as in Example 261. 
     The results obtained were as shown in Table 333. As Table 333 illustrates, superiorities in respective evaluation items were acknowledged for the drum. 
     EXAMPLE 265 
     An aluminum cylinder was subjected to anodic oxidation to form an aluminum oxide (Al 2  O 3 ) layer to be a charge injection inhibition layer thereon, and a photoconductive layer then a surface layer were continuously formed on the previously formed charge injection inhibition layer under the conditions shown in Table 334(a) and Table 334(b) following the procedure of Example 261. 
     The resultant drum was evaluated by the same manners as in Example 261. The results obtained were as shown in Table 335. 
     As Table 335 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 266 
     A drum having an IR absorptive layer, a photoconductive layer and a surface layer was prepared under the condition shown in Table 336(a) and Table (b) and following the procedures of Example 261. 
     The resultant drum was evaluated by the same manners as in Example 261. 
     In addition, the drum was set with the conventional electrophotographic copying machine using a semiconductor laser beam of 785 nm in wavelength as the light source for image exposure in order to examine whether an infringe pattern appears or not on an image to be made. 
     The results obtained were as shown in Table 337. As Table 337 illustrates, superiorities in the respective evaluation items were acknowledged, and it was found that any infringe pattern did not appear on an image to be made. 
     EXAMPLE 267 
     A drum having a contact layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 338(a) and Table 338(b) and following the procedures of Example 261. 
     The resultant drum was evaluated by the same manners as in Example 261. The results obtained were as shown in Table 339. 
     As Table 339 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 268 
     A drum having an IR absorptive layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 340(a) and Table 340(b) and following the procedures of Example 261. The resultant drum was evaluated in the same way as in Example 266. The results obtained were as shown in Table 341. As Table 341 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 269 
     A drum having a contact layer, a charge injection inhibition layer, a photoconductive layer and a surface layer were prepared under the conditions shown in Table 342(a) and Table 342(b) and following the procedures of Example 261. The resultant drum was evaluated in the same way as in Example 261. The results obtained were as shown in Table 343. 
     As Table 343 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 270 
     A drum having a contact layer, an IR absorptive layer, a charge injection inhibition layer, a photoconductive layer and a surface layer was prepared under the conditions shown in Table 344(a) and Table 344(b) and following the procedures of Example 261. The resultant drum was evaluated in the same way as in Example 266. The results obtained were as shown in Table 345. As Table 345 illustrates, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 271 
     The procedures of Example 261 were repeated, except that the photoconductive layer forming conditions were  changed as shown in Table 346, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 272 
     The procedures of Example 262 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 347, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 273 
     The procedures of Example 263 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 348, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 274 
     The procedures of Example 264 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 349, to thereby prepare multiple drums. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 275 
     The procedures of Example 264 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 24 and Table 25, to thereby prepare multiple drums as shown in Table 350. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 276 
     The procedures of Example 264 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24. Table 27 and Table 351, to thereby prepare multiple drums as shown in Table 352. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 277 
     The procedures of Example 264 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24, Table 27 and Table 353, to thereby prepare multiple drums as shown in Table 354. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 278 
     The procedures of Example 265 were repeated, except that the photoconductive layer forming conditions were changed as shown in Table 25, to thereby prepare multiple drums as shown in Table 354. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 279 
     The procedures of Example 265 were repeated, except that the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 351, to thereby prepare multiple drums as shown in Table 356. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 280 
     The procedures of Example 265 were repeated, except that the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 353, to thereby prepare multiple drums as shown in Table 357. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 281 
     The procedures of Example 266 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 36, to thereby prepare multiple drums as shown in Table 358. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 282 
     The procedures of Example 266 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38 and the photoconductive layer forming conditions were changed as shown in Table 25, to thereby prepare multiple drums as shown in Table 359. 
     The resultant drums were evaluated in the same way  as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 283 
     The procedures of Example 266 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, and the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 351, to thereby prepare multiple drums as shown in Table 360. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 284 
     The procedures of Example 266 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, and the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 27 and Table 353, to thereby prepare multiple drums as shown in Table 361. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 285 
     The procedures of Example 267 were repeated, except that the contact layer forming conditions were changed as shown in Table 42, to thereby prepare multiple drums as shown in Table 362. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 286 
     The procedures of Example 267 were repeated, except that the contact layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 44 and Table 25, to thereby prepare multiple drums as shown in Table 363. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 287 
     The procedures of Example 267 were repeated, except that the contact layer forming conditions, photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 44. Table 27 and Table 351, to thereby prepare multiple drums as shown in Table 364. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 288 
     The procedures of Example 267 were repeated, except that the contact layer forming conditions, photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 44, Table 27 and Table 353, to thereby prepare multiple drums as shown in Table 365. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 289 
     The procedures of Example 268 were repeated, except that the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 36, to thereby prepare multiple drums as shown in Table 366. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 290 
     The procedures of Example 268 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 49 and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 367. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 291 
     The procedures of Example 268 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51 and Table 351, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 368. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 292 
     The procedures of Example 268 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51 and Table 353, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 369. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 293 
     The procedures of Example 269 were repeated, except that the contact layer forming conditions were changed as shown in Table 44 and Table 54, to thereby prepare multiple drums as shown in Table 370. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 294 
     The procedures of Example 269 were repeated, except that the change injection inhibition layer forming conditions were changed as shown in Table 56, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 371. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 295 
     The procedures of Example 269 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24 and Table 351,  and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 372. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 296 
     The procedures of Example 269 were repeated, except that the charge injection inhibition layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 24 and Table 353, and the contact layer forming conditions were changed as shown in Table 44 and Table 57, to thereby prepare multiple drums as shown in Table 373. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 297 
     The procedures of Example 270 were repeated, except that the charge injection inhibition layer forming conditions were changed as shown in Table 61, to thereby prepare multiple drums as shown in Table 374. The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 298 
     The procedures of Example 270 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed respectively as shown in Table 64 and Table 63, to thereby prepare multiple drums as shown in Table 375. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 299 
     The procedures of Example 270 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 64, Table 66 and Table 351, to thereby prepare multiple drums as shown in Table 376. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 300 
     The procedures of Example 270 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 64, Table 66 and Table 353, to thereby prepare multiple drums as shown in Table 377. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 301 
     The procedures of Example 268 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51. Table 69 and Table 378, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 379. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 302 
     The procedures of Example 268 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 378, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 380. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 303 
     The procedures of Example 268 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 351, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 381. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 304 
     The procedures of Example 268 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 351, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 382. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 305 
     The procedures of Example 268 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 69 and Table 353,and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 383. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 306 
     The procedures of Example 268 were repeated, except that the charge injection inhibition layer forming conditions, the photoconductive layer forming conditions and the surface layer forming conditions were changed respectively as shown in Table 51, Table 72 and Table 353, and the IR absorptive layer forming conditions were changed as shown in Table 35 and Table 38, to thereby prepare multiple drums as shown in Table 384. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 307 
     The procedures of Example 264 were repeated, except that the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 78 and the surface layer forming conditions were changed as shown in Table 353, to thereby prepare multiple drums as shown in Table 385. 
     The resultant drums were evaluated in the same way as in Example 261. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 308 
     The procedures of Example 268 were repeated, except that the IR absorptive layer forming conditions, the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 80 and the surface layer forming conditions were changed as shown in Table 353, to thereby prepare multiple drums as shown in Table 386. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 309 
     The procedures of Example 270 were repeated, except that the contact layer forming conditions, the IR absorptive layer forming conditions, the charge injection inhibition layer forming conditions and the photoconductive layer forming conditions were changed as shown in Table 82 and the surface layer forming conditions were changed as shown in Table 353, to thereby prepare multiple drums as shown in Table 387. 
     The resultant drums were evaluated in the same way as in Example 266. As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 310 
     A drum having a charge injection inhibition layer, a photoconductive layer, an intermediate layer and a surface layer was prepared under the conditions shown in Table 388 and following the procedures of Example 261. 
     The resultant drum was evaluated in the same way as in Example 261, superiorities in the respective evaluation items were acknowledged. 
     EXAMPLE 311 
     The mirror grinded cylinders were supplied for grinding process with cutting tool having various degrees. With the patterns of FIG. 3 and various cross section patterns as described in Table 85, multiple cylinders were provided. These cylinders were set to the fabrication apparatus of FIG. 2 accordingly, and used to prepare multiple drums under the same layer forming conditions of Example 261. The resulting drums were evaluated with the same procedures as in Example 261. 
     As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     EXAMPLE 312 
     The surface of mirror grinded cylinder was treated by dropping lots of bearing balls thereto to thereby form uneven shape composed of a plurality of fine dimples at the surface, and multiple cylinders having a cross section form of FIG. 4 and of a cross section pattern of Table 86 were provided These cylinders were set to the fabrication apparatus of FIG. 2 accordingly and used for the preparation of multiple drums under the same layer forming conditions of Example 261. The resulting drums were evaluated with the same procedures of Example 261. 
     As a result, it was found that every drum was provided with practically applicable desired electrophotographic characteristics. 
     
                                           TABLE 1__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Photo- SiH.sub.4 200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)           100              ppmlayer NO        4Surface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.35 0.5layer NH.sub.3  100__________________________________________________________________________ 
    
     
                                           TABLE 2__________________________________________________________________________Initial                 Increaseelectri-                of        BreakficationResidual Defective               Image                   defective                        Surface                             down                                 Abrasionefficiencyvoltage     Ghost         image flow                   image                        abrasion                             voltage                                 resistance__________________________________________________________________________○○     ⊚         ⊚               ○                   ○                        ⊚                             ⊚                                 ⊚__________________________________________________________________________ ⊚ : Excellent  ○  : Good Δ : Applicable for practical use X: Poor 
    
     
                                           TABLE 3__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Photo- SiH.sub.4 200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)           100              ppmlayer NO        4Surface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.40 0.5layer H.sub.2   100 NH.sub.3  100__________________________________________________________________________ 
    
     
                                           TABLE 4__________________________________________________________________________Initial                 Increaseelectri-                of        BreakficationResidual Defective               Image                   defective                        Surface                             down                                 Abrasionefficiencyvoltage     Ghost         image flow                   image                        abrasion                             voltage                                 resistance__________________________________________________________________________○○     ⊚         ⊚               ○                   ○                        ⊚                             ⊚                                 ⊚__________________________________________________________________________ ⊚ : Excellent  ○  : Good Δ : Applicable for practical use X: Poor 
    
     
                                           TABLE 5__________________________________________________________________________Initial                 Increaseelectri-                of        BreakficationResidual Defective               Image                   defective                        Surface                             down                                 Abrasionefficiencyvoltage     Ghost         image flow                   image                        abrasion                             voltage                                 resistance__________________________________________________________________________○○     ⊚         ⊚               ○                   ○                        ⊚                             ⊚                                 ⊚__________________________________________________________________________ ⊚ : Excellent  ○  : Good Δ : Applicable for practicle use X: Poor 
    
     
                                           TABLE 6__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Charge SiH.sub.4 100   250    150   0.35  3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppmlayer NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.35 0.5layer NH.sub.3  100__________________________________________________________________________ 
    
     
                                           TABLE 7__________________________________________________________________________Initial                 Increaseelectri-                of        BreakficationResidual Defective               Image                   defective                        Surface                             down                                 Abrasionefficiencyvoltage     Ghost         image flow                   image                        abrasion                             voltage                                 resistance__________________________________________________________________________⊚○     ⊚         ⊚               ○                   ○                        ⊚                             ⊚                                 ⊚__________________________________________________________________________ ⊚ : Excellent  ○  : Good Δ : Applicable for practical use X: Poor 
    
     
                                           TABLE 8__________________________________________________________________________ Gas used and its            Substrate    Inner                              LayerName of flow rate  temperature                   RF power                         pressure                              thicknesslayer (SCCM)     (°C.)                   (W)   (Torr)                              (μm)__________________________________________________________________________Photo- SiH.sub.4         200            250    300   0.40 20conductive H.sub.2 200layerSurface B.sub.2 H.sub.6 /Ar (20%)         500            250    200   0.35 0.5layer NH.sub.3         100__________________________________________________________________________ 
    
     
                                           TABLE 9__________________________________________________________________________Initial                 Increaseelectri-                of        BreakficationResidual Defective               Image                   defective                        Surface                             down                                 Abrasionefficiencyvoltage     Ghost         image flow                   image                        abrasion                             voltage                                 resistance__________________________________________________________________________⊚○     ⊚         ⊚               ○                   ○                        ⊚                             ⊚                                 ⊚__________________________________________________________________________ ⊚ : Excellent  ○  : Good Δ : Applicable for practical use X: Poor 
    
     
                                           TABLE 10__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________IR    SiH.sub.4 100   250    150   0.35  1absorptive H.sub.2   100layer GeH.sub.4 50 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.35 0.5layer NH.sub.3  100__________________________________________________________________________ 
    
     
                                           TABLE 11__________________________________________________________________________Initial                 Increaseelectri-                of        BreakficationResidual Defective               Image                   defective                        Surface                             down                                 Abrasion                                      Interferenceefficiencyvoltage     Ghost         image flow                   image                        abrasion                             voltage                                 resistance                                      fringe__________________________________________________________________________○○     ⊚         ⊚               ○                   ○                        ⊚                             ⊚                                 ⊚                                      ○__________________________________________________________________________ ⊚ : Excellent  ○  : Good Δ : Applicable for practical use X Poor 
    
     
                                           TABLE 12__________________________________________________________________________ Gas used and its            Substrate    Inner                              LayerName of flow rate  temperature                   RF power                         pressure                              thicknesslayer (SCCM)     (°C.)                   (W)   (Torr)                              (μm)__________________________________________________________________________Contact SiH.sub.4          20            250    100   0.25 0.5layer N.sub.2 100Photo- SiH.sub.4         200            250    300   0.40 20conductive H.sub.2 200layerSurface B.sub.2 H.sub.6 /Ar (20%)         500            250    200   0.35 0.5layer NH.sub.3         100__________________________________________________________________________ 
    
     
                                           TABLE 13__________________________________________________________________________Initial                 Increaseelectri-                of        BreakficationResidual Defective               Image                   defective                        Surface                             down                                 Abrasionefficiencyvoltage     Ghost         image flow                   image                        abrasion                             voltage                                 resistance__________________________________________________________________________⊚○     ⊚         ⊚               ○                   ○                        ⊚                             ⊚                                 ⊚__________________________________________________________________________ ⊚ : Excellent  ○  : Good Δ : Applicable for practical use X: Poor 
    
     
                                           TABLE 14__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________IR    SiH.sub.4 100   250    150   0.35 1absorptive H.sub.2   100layer GeH.sub.4 50 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm NO        10Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppmlayer NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.35 0.5layer NH.sub.3  100__________________________________________________________________________ 
    
     
                                           TABLE 15__________________________________________________________________________Initial electri-     Residual Defective                    Image                         Increase of                                 Surface                                      Break down                                             Abrasion                                                   Interferencefication efficiency     voltage          Ghost              image flow defective image                                 abrasion                                      voltage                                             resistance                                                   fringe__________________________________________________________________________⊚     ○          ⊚              ⊚                    ○                         ○                                 ⊚                                      ⊚                                             ⊚                                                   ○__________________________________________________________________________ ⊚ : Excellent  ○  : Good Δ : Applicable for practical use X: Poor 
    
     
                                           TABLE 16__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Contact SiH.sub.4 20    250     50   0.05 0.5layer N.sub.2   10Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppmlayer NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.35 0.5layer NH.sub.3  100__________________________________________________________________________ 
    
     
                                           TABLE 17__________________________________________________________________________Initial electri-    Residual Defective                   Image                       Increase of                               Surface                                    Break  Abrasionfication efficiency    voltage         Ghost             image flow                       defective image                               abrasion                                    down voltage                                           resistance__________________________________________________________________________⊚    ○         ⊚             ⊚                   ⊚                       ○                               ○                                    ⊚                                           ⊚__________________________________________________________________________ ⊚ : Excellent  ○  : Good Δ : Applicable for practical use X: Poor 
    
     
                                           TABLE 18__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Contact SiH.sub.4 20    250     50   0.05 0.5layer N.sub.2   10IR    SiH.sub.4 100   250    150   0.35 1absorptive H.sub.2   100layer GeH.sub.4 50 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm NO        10Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppmlayer NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.35 0.5layer NH.sub.3  100__________________________________________________________________________ 
    
     
                                           TABLE 19__________________________________________________________________________Intial electri-     Residual Defective                    Image                         Increase of                                 Surface                                      Break down                                             Abrasion                                                   Interferencefication efficiency     voltage          Ghost              image flow defective image                                 abrasion                                      voltage                                             resistance                                                   fringe__________________________________________________________________________⊚     ○          ⊚              ⊚                    ○                         ○                                 ⊚                                      ⊚                                             ⊚                                                   ○__________________________________________________________________________ ⊚ : Excellent  ○  : Good Δ : Applicable for practical use X: Poor 
    
     
                                           TABLE 20__________________________________________________________________________    Gas used and its               Substrate    Inner                                 LayerDrum    flow rate       temperature                      RF power                            pressure                                 thicknessNo. (SCCM)          (°C.)                      (W)   (Torr)                                 (μm)__________________________________________________________________________1101    SiH.sub.4 200   250    300   0.40 20    He        200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        41102    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        61103    SiH.sub.4 200   250    300   0.40 20    H.sub.2   2001104    SiH.sub.4 200   250    250   0.40 20    Ar        2001105    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200__________________________________________________________________________ 
    
     
                                           TABLE 21__________________________________________________________________________    Gas used and its               Substrate    Inner                                 LayerDrum    flow rate       temperature                      RF power                            pressure                                 thicknessNo. (SCCM)          (°C.)                      (W)   (Torr)                                 (μm)__________________________________________________________________________1201    SiH.sub.4 200   250    300   0.40 20    He        200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        41202    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        61203    SiH.sub.4 200   250    300   0.40 20    H.sub.2   2001204    SiH.sub.4 200   250    250   0.40 20    Ar        2001205    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200__________________________________________________________________________ 
    
     
                                           TABLE 22__________________________________________________________________________    Gas used and its               Substrate    Inner                                 LayerDrum    flow rate       temperature                      RF power                            pressure                                 thicknessNo. (SCCM)          (°C.)                      (W)   (Torr)                                 (μm)__________________________________________________________________________1301    SiH.sub.4 200   250    300   0.40 20    He        200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        41302    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        61303    SiH.sub.4 200   250    300   0.40 20    H.sub.2   2001304    SiH.sub.4 200   250    250   0.40 20    Ar        2001305    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200__________________________________________________________________________ 
    
     
                                           TABLE 23__________________________________________________________________________    Gas used and its   Substrate    Inner                                    LayerDrum    flow rate          temperature                         RF power                               pressure                                    thicknessNo. (SCCM)             (°C.)                         (W)   (Torr)                                    (μm)__________________________________________________________________________1401    SiH.sub.4 100      250    150   0.35 3    H.sub.2   100    B.sub.2 H.sub.6 (against SiH.sub.4)         1000  ppm    GeH.sub.4 10    NO        101402    SiH.sub.4 80       250    170   0.25 3    SiF.sub.4 20    B.sub.2 H.sub.6 (against SiH.sub.4)         1000  ppm    SnH.sub.4 5    NO        51403    SiH.sub.4 100      250    130   0.25 3    B.sub.2 H.sub.6 (against SiH.sub.4)         800   ppm    NO        4    N.sub.2   4    CH.sub.4  61404    SiH.sub.4 100      250    150   0.35 3    H.sub.2   100    PH.sub.3 (against SiH.sub.4)         800   ppm1405    SiH.sub.4 100      250    130   0.25 3    PH.sub.3 (against SiH.sub.4)         800   ppm    GeH.sub.4 10    NO        101406    SiH.sub.4 100      250    150   0.35 3    H.sub.2   100    B.sub.2 H.sub.6 (against SiH.sub.4)         1000  ppm    NO*       10    NO**      10→ 0 ***__________________________________________________________________________ *Substrate side 2 μm **Surface layer side 1 μm ***Constantly changed 
    
     
                                           TABLE 24__________________________________________________________________________Gas used and its   Substrate    Inner                                     LayerName offlow rate          temperature                          RF power                                pressure                                     thicknesslayer(SCCM)             (°C.)                          (W)   (Torr)                                     (μm)__________________________________________________________________________ChargeSiH.sub.4 100      250    150   0.35 3injectionH.sub.2   100inhibitionB.sub.2 H.sub.6 (against SiH.sub.4)          1000  ppmlayer 1NO        10ChargeSiH.sub.4 100      250    150   0.35 3injectionH.sub.2   100inhibitionB.sub.2 H.sub.6 (against SiH.sub.4)          1000  ppmlayer 2GeH.sub.4 10NO        10ChargeSiH.sub.4 80       250    170   0.25 3injectionSiF.sub.4 20inhibitionB.sub.2 H.sub.6 (against SiH.sub.4)          1000  ppmlayer 3SnH.sub.4 5NO        5ChargeSiH.sub.4 100      250    130   0.25 3injectionB.sub.2 H.sub.6 (against SiH.sub.4)          800   ppminhibitionNO        4layer 4N.sub.2   4CH.sub.4  6ChargeSiH.sub.4 100      250    150   0.35 3injectionH.sub.2   100inhibitionPH.sub.3 (against SiH.sub.4)          800   ppmlayer 5ChargeSiH.sub. 4          100      250    130   0.25 3injectionPH.sub.3 (against SiH.sub.4)          800   ppminhibitionGeH.sub.4 10layer 6NO        10ChargeSiH.sub.4 100      250    150   0.35 3injectionH.sub.2   100inhibitionB.sub.2 H.sub.6 (against SiH.sub.4)          1000  ppmlayer 7NO*       10NO**      10→ 0***__________________________________________________________________________ *substrate side 2 μm **surface layer side 2 μm ***constantly changed 
    
     
                                           TABLE 25__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Photo- SiH.sub.4 200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)           100              ppmlayer 1 NO        4Photo- SiH.sub.4 200   250    300   0.40 20conductive He        200layer 2 B.sub.2 H.sub.6 (against SiH.sub.4)           100              ppm NO        4Photo- SiH.sub.4 150   250    350   0.40 20conductive SiF.sub.4 50layer 3 H.sub.2   200 B.sub.2 H.sub.6 (against SiH.sub.4)           100              ppm NO        6Photo- SiH.sub.4 200   250    250   0.40 20conductive Ar        200layer 5Photo- SiH.sub.4 150   250    350   0.40 20conductive SiF.sub.4 50layer 6 H.sub.2   200__________________________________________________________________________ 
    
     
                                           TABLE 26__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5                          layer 6                               layer 7__________________________________________________________________________Photo- 1501 1506 1511 1516 1521 1526 1531conductivelayer 1Photo- 1502 1507 1512 1517 1522 1527 1532conductivelayer 2Photo- 1503 1508 1513 1518 1523 1528 1533conductivelayer 3Photo- 1504 1509 1514 1519 1524 1529 1534conductivelayer 5Photo- 1505 1510 1515 1520 1525 1530 1535conductivelayer 6__________________________________________________________________________ 
    
     
                                           TABLE 27__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Photo- SiH.sub.4 200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)           100              ppmlayer 1 NO        4Photo- SiH.sub.4 200   250    300   0.40 20conductive He        200layer 2 B.sub.2 H.sub.6 (against SiH.sub.4)           100              ppm NO        4Photo- SiH.sub.4 150   250    350   0.40 20conductive SiF.sub.4 50layer 3 H.sub.2   200 B.sub.2 H.sub.6 (against SiH.sub.4)           100              ppm NO        6Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layer 4Photo- SiH.sub.4 200   250    250   0.40 20conductive Ar        200layer 5Photo- SiH.sub.4 150   250    350   0.40 20conductive SiF.sub.4 50layer 6 H.sub.2   200__________________________________________________________________________ 
    
     
                                           TABLE 28__________________________________________________________________________Gas used and its           Substrate    Inner                             LayerName offlow rate  temperature                  RF power                        pressure                             thicknesslayer(SCCM)     (°C.)                  (W)   (Torr)                             (μm)__________________________________________________________________________SurfaceB.sub.2 H.sub.6 /Ar (20%)        500           250    200   0.40 0.5layerH.sub.2 100NH.sub.3        100__________________________________________________________________________ 
    
     
                                           TABLE 29__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5                          layer 6                               layer 7__________________________________________________________________________Photo- 1601 1607 1613 1619 1625 1631 1637conductivelayer 1Photo- 1602 1608 1614 1620 1626 1632 1638conductivelayer 2Photo- 1603 1609 1615 1621 1627 1633 1639conductivelayer 3Photo- 1604 1610 1616 1622 1628 1634 1640conductivelayer 4Photo- 1605 1611 1617 1623 1629 1635 1641conductivelayer 5Photo- 1606 1612 1618 1624 1630 1636 1642conductivelayer 6__________________________________________________________________________ 
    
     
                                           TABLE 30__________________________________________________________________________Gas used and its           Substrate    Inner                             LayerName offlow rate  temperature                  RF power                        pressure                             thicknesslayer(SCCM)     (°C.)                  (W)   (Torr)                             (μm)__________________________________________________________________________SurfaceB.sub.2 H.sub.6 /Ar (20%)        500           250    200   0.35 0.5layerNH.sub.3        100Bias voltage ofthe cyclinder-150 V__________________________________________________________________________ 
    
     
                                           TABLE 31__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5                          layer 6                               layer 7__________________________________________________________________________Photo- 1701 1707 1713 1719 1725 1731 1737conductivelayer 1Photo- 1702 1708 1714 1720 1726 1732 1738conductivelayer 2Photo- 1703 1709 1715 1721 1727 1733 1739conductivelayer 3Photo- 1704 1710 1716 1722 1728 1734 1740conductivelayer 4Photo- 1705 1711 1717 1723 1729 1735 1741conductivelayer 5Photo- 1706 1712 1718 1724 1730 1736 1742conductivelayer 6__________________________________________________________________________ 
    
     
                       TABLE 32______________________________________                 Photo-   Photo- Photo-Photo-      Photo-    conduc-  conduc-                                 conduc-conductive  conductive                 tive     tive   tiveLayer 1     Layer 2   Layer 3  Layer 5                                 Layer 6______________________________________Drum  1801      1802      1803   1804   1805No.______________________________________ 
    
     
                                           TABLE 33__________________________________________________________________________Photo-    Photo-           Photo-                 Photo-                       Photo-                             Photo-conductive     conductive           conductive                 conductive                       conductive                             conductiveLayer 1   Layer 2           Layer 3                 Layer 4                       Layer 5                             Layer 6__________________________________________________________________________Drum    1901  1902  1903  1904  1905  1906No.__________________________________________________________________________ 
    
     
                                           TABLE 34__________________________________________________________________________Photo-    Photo-           Photo-                 Photo-                       Photo-                             Photo-conductive     conductive           conductive                 conductive                       conductive                             conductiveLayer 1   Layer 2           Layer 3                 Layer 4                       Layer 5                             Layer 6__________________________________________________________________________Drum    2001  2002  2003  2004  2005  2006No.__________________________________________________________________________ 
    
     
                                           TABLE 35__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________IR    SiH.sub.4 100   250    150   0.35 1absorptive GeH.sub.4 50layer 1 H.sub.2   100IR    SiH.sub.4 100   250    150   0.35 1absorptive GeH.sub.4 50layer 2 NO        10 H.sub.2   100IR    SiH.sub.4 100   250    150   0.35 1absorptive SnH.sub.4 50layer 3 NO        10 H.sub.2   100IR    SiH.sub.4 100   250    150   0.35 1absorptive GeH.sub.4 50layer 4 N.sub.2   4 NO        4 CH.sub.4  6IR    SiH.sub.4 100   250    150   0.35 1absorptive SnH.sub.4 50layer 5 N.sub.2   4 NO        4 CH.sub.4  6IR    SiH.sub.4 100   250    150   0.35 1absorptive GeH.sub.4 50layer 6 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm H.sub.2   100IR    SiH.sub.4 100   250    150   0.35 1absorptive GeH.sub.4 50layer 7 B.sub. 2 H.sub.6 (against SiH.sub.4)           1000              ppm NO        10 CH.sub.4  100IR    SiH.sub.4 100   250    150   0.35 1absorptive GeH.sub.4 50layer 8 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm CH.sub.4  20 H.sub.2   100IR    SiH.sub.4 100   250    150   0.35 1absorptive SnH.sub.4 50layer 9 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm H.sub.2   100IR    SiH.sub.4 100   250    150   0.35 1absorptive GeH.sub.4 50layer 10 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm NO        4 N.sub.2   4 CH.sub.4  6__________________________________________________________________________ 
    
     
                                           TABLE 36__________________________________________________________________________ Gas used and its   Substrate    Inner                                      LayerName of flow rate          temperature                           RF power                                 pressure                                      thicknesslayer (SCCM)             (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________IR    SiH.sub.4 100      250    150   0.35 1absorptive GeH.sub.4 50layer 11 SiF.sub.4 10 PH.sub.3 (against SiH.sub.4)           800   ppmIR    SiH.sub.4 100      250    150   0.35 1absorptive GeH.sub.4 50layer 12 PH.sub.3 (against SiH.sub.4)           800   ppm NO        10IR    SiH.sub.4 100      250    150   0.35 1absorptive GeH.sub.4 50layer 13 PH.sub.3 (against SiH.sub.4)           800   ppm N.sub.2   10IR    SiH.sub.4 100      250    150   0.35 1absorptive SnH.sub.4 50layer 14 PH.sub.3 (against SiH.sub.4)           800   ppm NO        10IR    SiH.sub.4 100      250    170   0.35 1absorptive SnH.sub.4 50layer 15 PH.sub.3 (against SiH.sub.4)           800   ppm NO        4 N.sub.2   4 CH.sub.4  6IR    SiH.sub.4 100      250    150   0.35 1absorptive SnH.sub. 4           50layer 17 PH.sub.3 (against SiH.sub.4)           800   ppmIR    SiH.sub.4 100      250    150   0.35 1absorptive GeH.sub.4 50layer 18 SnH.sub.4 50 H.sub.2   100IR    SiH.sub.4 100      250    150   0.35 1absorptive GeH.sub.4 50layer 19 SnH.sub.4 50 NO        4 H.sub.2   100IR    SiH.sub.4 100      250    150   0.35 1absorptive GeH.sub.4*           50layer 20 GeH.sub.4**           50 → 0*** H.sub.2   100__________________________________________________________________________ *substrate side 0.7 μm **surface layer side 0.3 μm ***constantly decreased 
    
     
                       TABLE 37______________________________________         Drum         No.______________________________________IR Absorptive   2101Layer 1IR Absorptive   2102Layer 2IR Absorptive   2103Layer 3IR Absorptive   2104Layer 4IR Absorptive   2105Layer 5IR Absorptive   2106Layer 6Ir Absorptive   2107Layer 7IR Absorptive   2108Layer 8IR Absorptive   2109Layer 9IR Absorptive   2110Layer 10IR Absorptive   2111Layer 11IR Absorptive   2112Layer 12IR Absorptive   2113Layer 13IR Absorptive   2114Layer 14IR Absorptive   2115Layer 15IR Absorptive   2116Layer 17IR Absorptive   2117Layer 18IR Absorptive   2118Layer 19IR Absorptive   2119Layer 20______________________________________ 
    
     
                                           TABLE 38__________________________________________________________________________ Gas used and its   Substrate    Inner                                      LayerName of flow rate          temperature                           RF power                                 pressure                                      thicknesslayer (SCCM)             (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________IR    SiH.sub.4 100      250    150   0.35 1absorptive GeH.sub.4 50layer 11 SiF.sub.4 10 PH.sub.3 (against SiH.sub.4)           800   ppmIR    SiH.sub.4 100      250    150   0.35 1absorptive GeH.sub.4 50layer 12 PH.sub.3 (against SiH.sub.4)           800   ppm NO        10IR    SiH.sub.4 100      250    150   0.35 1absorptive GeH.sub.4 50layer 13 PH.sub.3 (against SiH.sub.4)           800   ppm N.sub.2   10IR    SiH.sub.4 100      250    150   0.35 1absorptive SnH.sub.4 50layer 14 PH.sub.3 (against SiH.sub.4)           800   ppm NO        10IR    SiH.sub.4 100      250    170   0.35 1absorptive SnH.sub.4 50layer 15 PH.sub.3 (against SiH.sub.4)           800   ppm NO        4 N.sub.2   4 CH.sub.4  6IR    SiH.sub.4 100      250    150   0.35 1absorptive GeH.sub.4 50layer 16 B.sub.2 H.sub.6 (against SiH.sub.4)           1000  ppm NO        10 H.sub.2   100IR    SiH.sub.4 100      250    150   0.35 1absorptive SnH.sub.4 50layer 17 PH.sub.3 (against SiH.sub.4)           800   ppmIR    SiH.sub.4 100      250    150   0.35 1absorptive GeH.sub.4 50layer 18 SnH.sub.4 50 H.sub.2   100IR    SiH.sub.4 100      250    150   0.35 1absorptive GeH.sub.4 50layer 19 SnH.sub.4 50 NO        4 H.sub.2   100IR    SiH.sub.4 100      250    150   0.35 1absorptive GeH.sub.4*           50layer 20 GeH.sub.4**           50 → 0*** H.sub.2   100__________________________________________________________________________ *substrate side 0.7 μm **surface layer side 0.3 μm ***constantly decreased 
    
     
                       TABLE 39______________________________________     Photo-   Photo-  Photo- Photo-                                   Photo-     con-     con-    con-   con-  con-Drum      ductive  ductive ductive                             ductive                                   ductiveNo.       layer 1  layer 2 layer 3                             layer 5                                   layer 6______________________________________IR absorptive     2201     2221    2241   2261  2281layer 1IR absorptive     2202     2222    2242   2262  2282layer 2IR absorptive     2203     2223    2243   2263  2283layer 3IR absorptive     2204     2224    2244   2264  2284layer 4IR absorptive     2205     2225    2245   2265  2285layer 5IR absorptive     2206     2226    2246   2266  2286layer 6IR absorptive     2207     2227    2247   2267  2287layer 7IR absorptive     2208     2228    2248   2268  2288layer 8IR absorptive     2209     2229    2249   2269  2289layer 9IR absorptive     2210     2230    2250   2270  2290layer 10IR absorptive     2211     2231    2251   2271  2291layer 11IR absorptive     2212     2232    2252   2272  2292layer 12IR absorptive     2213     2233    2253   2273  2293layer 13IR absorptive     2214     2234    2254   2274  2294layer 14IR absorptive     2215     2235    2255   2275  2295layer 15IR absorptive     2216     2236    2256   2276  2296layer 16IR absorptive     2217     2237    2257   2277  2297layer 17IR absorptive     2218     2238    2258   2278  2298layer 18IR absorptive     2219     2239    2259   2279  2299layer 19IR absorptive     2220     2240    2260   2280  22100layer 20______________________________________ 
    
     
                                           TABLE 40__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-                                Photo-Drum   conductive        conductive              conductive                    conductive                          conductive                                conductiveNo.    layer 1        layer 2              layer 3                    layer 4                          layer 5                                layer 6__________________________________________________________________________IR absorptive  2301  2321  2341  2361  2381  23101layer 1IR absorptive  2302  2322  2342  2362  2382  23102layer 2IR absorptive  2303  2323  2343  2363  2383  23103layer 3IR absorptive  2304  2324  2344  2364  2384  23104layer 4IR absorptive  2305  2325  2345  2365  2385  23105layer 5IR absorptive  2306  2326  2346  2366  2386  23106layer 6IR absorptive  2307  2327  2347  2367  2387  23107layer 7IR absorptive  2308  2328  2348  2368  2388  23108layer 8IR absorptive  2309  2329  2349  2369  2389  23109layer 9IR absorptive  2310  2330  2350  2370  2390  23110layer 10IR absorptive  2311  2331  2351  2371  2391  23111layer 11IR absorptive  2312  2332  2352  2372  2392  23112layer 12IR absorptive  2313  2333  2353  2373  2393  23113layer 13IR absorptive  2314  2334  2354  2374  2394  23114layer 14IR absorptive  2315  2335  2355  2375  2395  23115layer 15IR absorptive  2316  2336  2356  2376  2396  23116layer 16IR absorptive  2317  2337  2357  2377  2397  23117layer 17IR absorptive  2318  2338  2358  2378  2398  23118layer 18IR absorptive  2319  2339  2359  2379  2399  23119layer 19IR absorptive  2320  2340  2360  2380  23100 23120layer 20__________________________________________________________________________ 
    
     
                                           TABLE 41__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-                                Photo-Drum   conductive        conductive              conductive                    conductive                          conductive                                conductiveNo.    layer 1        layer 2              layer 3                    layer 4                          layer 5                                layer 6__________________________________________________________________________IR absorptive  2401  2421  2441  2461  2481  24101layer 1IR absorptive  2402  2422  2442  2462  2482  24102layer 2IR absorptive  2403  2423  2443  2463  2483  24103layer 3IR absorptive  2404  2424  2444  2464  2484  24104layer 4IR absorptive  2405  2425  2445  2465  2485  24105layer 5IR absorptive  2406  2426  2446  2466  2486  24106layer 6IR absorptive  2407  2427  2447  2467  2487  24107layer 7IR absorptive  2408  2428  2448  2468  2488  24108layer 8IR absorptive  2409  2429  2449  2469  2489  24109layer 9IR absorptive  2410  2430  2450  2470  2490  24110layer 10Ir absorptive  2411  2431  2451  2471  2491  24111layer 11IR absorptive  2412  2432  2452  2472  2492  24112layer 12IR absorptive  2413  2433  2453  2473  2493  24113layer 13IR absorptive  2414  2434  2454  2474  2494  24114layer 14IR absorptive  2415  2435  2455  2475  2495  24115layer 15IR absorptive  2416  2436  2456  2476  2496  24116layer 16IR absorptive  2417  2437  2457  2477  2497  24117layer 17IR absorptive  2418  2438  2458  2478  2498  24118layer 18IR absorptive  2419  2439  2459  2479  2499  24119layer 19IR absorptive  2420  2440  2460  2480  21400 24120layer 20__________________________________________________________________________ 
    
     
                                           TABLE 42__________________________________________________________________________Gas used and its        Substrate    Inner LayerName offlow rate        temperature               RF power                     pressure                           thicknesslayer(SCCM)  (°C.)               (W)   (Torr)                           (μm)__________________________________________________________________________ContactSiH.sub.4     20 250    100   0.25  0.5layer 2No   20ContactSiH.sub.4     20 250    150   0.25  0.5layer 3CH.sub.4    400H.sub.2    100ContactSiH.sub.4     10 250    100   0.25  0.5layer 4SiF.sub.4     10NO   10N.sub.2     50CH.sub.4    200__________________________________________________________________________ 
    
     
                       TABLE 43______________________________________Contact           Contact  ContactLayer 2           Layer 3  Layer 4______________________________________Drum    2501          2502     2503No.______________________________________ 
    
     
                                           TABLE 44__________________________________________________________________________Gas used and its        Substrate    Inner LayerName offlow rate        temperature               RF power                     pressure                           thicknesslayer(SCCM)  (°C.)               (W)   (Torr)                           (μm)__________________________________________________________________________ContactSiH.sub.4     20 250    100   0.25  0.5layer 1N.sub.2    100ContactSiH.sub.4     20 250    100   0.25  0.5layer 2NO   10ContactSiH.sub.4     20 250    150   0.25  0.5layer 3CH.sub.4    400H.sub.2    100ContactSiH.sub.4     10 250    100   0.25  0.5layer 4SiF.sub.4     10NO   10N.sub.2     50CH.sub.4    200__________________________________________________________________________ 
    
     
                       TABLE 45______________________________________Drum     Contact  Contact    Contact                               ContactNo.      layer 1  layer 2    layer 3                               layer 4______________________________________Photo-   2601     2607       2613   2619conductivelayer 1Photo-   2602     2608       2614   2620conductivelayer 2Photo-   2603     2609       2615   2621conductivelayer 3Photo-   2604     2610       2616   2622conductivelayer 4Photo-   2605     2611       2617   2623conductivelayer 5Photo-   2606     2612       2618   2624conductivelayer 6______________________________________ 
    
     
                       TABLE 46______________________________________Drum     Contact  Contact    Contact                               ContactNo.      layer 1  layer 2    layer 3                               layer 4______________________________________Photo-   2701     2707       2713   2719conductivelayer 1Photo-   2702     2708       2714   2720conductivelayer 2Photo-   2703     2709       2715   2721conductivelayer 3Photo-   2704     2710       2716   2722conductivelayer 4Photo-   2705     2711       2717   2723conductivelayer 5Photo-   2706     2712       2718   2724conductivelayer 6______________________________________ 
    
     
                       TABLE 47______________________________________Drum     Contact  Contact    Contact                               ContactNo.      layer 1  layer 2    layer 3                               layer 4______________________________________Photo-   2801     2807       2813   2819conductivelayer 1Photo-   2802     2808       2814   2820conductivelayer 2Photo-   2803     2809       2815   2821conductivelayer 3Photo-   2804     2810       2816   2822conductivelayer 4Photo-   2805     2811       2817   2823conductivelayer 5Photo-   2806     2812       2818   2824conductivelayer 6______________________________________ 
    
     
                       TABLE 48______________________________________    Drum                Drum    No.                 No.______________________________________IR absorptive      2901       IR absorptive                            2911layer 1               layer 11IR absorptive      2902       IR absorptive                            2912layer 2               layer 12IR absorptive      2903       IR absorptive                            2913layer 3               layer 13IR absorptive      2904       IR absorptive                            2914layer 4               layer 14IR absorptive      2905       IR absorptive                            2915layer 5               layer 15IR absorptive      2906       IR absorptive                            2917layer 6               layer 17IR absorptive      2907       IR absorptive                            2918layer 7               layer 18IR absorptive      2908       IR absorptive                            2919layer 8               layer 19IR absorptive      2909       IR absorptive                            2920layer 9               layer 20IR absorptive      2910layer 10______________________________________ 
    
     
                                           TABLE 49__________________________________________________________________________Gas used and its   Substrate    Inner                                     LayerName offlow rate          temperature                          RF power                                pressure                                     thicknesslayer(SCCM)             (°C.)                          (W)   (Torr)                                     (μm)__________________________________________________________________________ChargeSiH.sub.4 100      250    130   0.25 3injectionB.sub.2 H.sub.6 (against SiH.sub.4)          800   ppminhibitionNO        4layer 4N.sub.2   4CH.sub.4  6ChargeSiH.sub.4 100      250    150   0.35 3injectionH.sub.2   100inhibitionPH.sub.3 (against SiH.sub.4)          800   ppmlayer 5ChargeSiH.sub.4 100      250    150   0.35 3injectionH.sub.2   100inhibitionB.sub.2 H.sub.6 (against SiH.sub.4)          1000  ppmlayer 7NO*       10NO**      10 → 0***__________________________________________________________________________ *substrate side 2 μm **surface layer side 2 μm ***constantly changed 
    
     
                       TABLE 50______________________________________     Photo-       Photo-    Photo-Drum      conductive   conductive                            conductiveNo.       layer 4      layer 5   layer 7______________________________________IR absorptive     3001         3021      3041layer 1IR absorptive     3002         3022      3042layer 2IR absorptive     3003         3023      3043layer 3IR absorptive     3004         3024      3044layer 4IR absorptive     3005         3025      3045layer 5IR absorptive     3006         3026      3046layer 6IR absorptive     3007         3027      3047layer 7IR absorptive     3008         3028      3048layer 8IR absorptive     3009         3029      3049layer 9IR absorptive     3010         3030      3050layer 10IR absorptive     3011         3031      3051layer 11IR absorptive     3012         3032      3052layer 12IR absorptive     3013         3033      3053layer 13IR absorptive     3014         3034      3054layer 14IR absorptive     3015         3035      3055layer 15IR absorptive     3016         3036      3056layer 16IR absorptive     3017         3037      3057layer 17IR absorptive     3018         3038      3058layer 18IR absorptive     3019         3039      3059layer 19IR absorptive     3020         3040      3060layer 20______________________________________ 
    
     
                                           TABLE 51__________________________________________________________________________Gas used and its   Substrate    Inner                                     LayerName offlow rate          temperature                          RF power                                pressure                                     thicknesslayer(SCCM)             (°C.)                          (W)   (Torr)                                     (μm)__________________________________________________________________________ChargeSiH.sub.4 100      250    150   0.35 3injectionH.sub.2   100inhibitionB.sub.2 H.sub.6 (against SiH.sub.4)          1000  ppmlayer 1NO        10ChargeSiH.sub.4 100      250    130   0.25 3injectionB.sub.2 H.sub.6 (against SiH.sub.4)          800   ppminhibitionNO        4layer 4N.sub.2   4CH.sub.4  6ChargeSiH.sub.4 100      250    150   0.35 3injectionH.sub.2   100inhibitionPH.sub.3 (against SiH.sub.4)          800   ppmlayer 5ChargeSiH.sub.4 100      250    150   0.35 3injectionH.sub.2   100inhibitionB.sub.2 H.sub.6 (against SiH.sub.4)          1000  ppmlayer 7NO*       10NO**      10 → 0***__________________________________________________________________________ *substrate side 2 μm **surface layer side 2 μm ***constantly changed 
    
     
                       TABLE 52______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    3101      3121      3141    3161layer 1IR absorptive    3102      3122      3142    3162layer 2IR absorptive    3103      3123      3143    3163layer 3IR absorptive    3104      3124      3144    3164layer 4IR absorptive    3105      3125      3145    3165layer 5IR absorptive    3106      3126      3146    3166layer 6IR absorptive    3107      3127      3147    3167layer 7IR absorptive    3108      3128      3148    3168layer 8IR absorptive    3109      3129      3149    3169layer 9IR absorptive    3110      3130      3150    3170layer 10IR absorptive    3111      3131      3151    3171layer 11IR absorptive    3112      3132      3152    3172layer 12IR absorptive    3113      3133      3153    3173layer 13IR absorptive    3114      3134      3154    3174layer 14IR absorptive    3115      3135      3155    3175layer 15IR absorptive    3116      3136      3156    3176layer 16IR absorptive    3117      3137      3157    3177layer 17IR absorptive    3118      3138      3158    3178layer 18IR absorptive    3119      3139      3159    3179layer 19IR absorptive    3120      3140      3160    3180layer 20______________________________________ 
    
     
                       TABLE 53______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    3201      3221      3241    3261layer 1IR absorptive    3202      3222      3242    3262layer 2IR absorptive    3203      3223      3243    3263layer 3IR absorptive    3204      3224      3244    3264layer 4IR absorptive    3205      3225      3245    3265layer 5IR absorptive    3206      3226      3246    3266layer 6IR absorptive    3207      3227      3247    3267layer 7IR absorptive    3208      3228      3248    3268layer 8IR absorptive    3209      3229      3249    3269layer 9IR absorptive    3210      3230      3250    3270layer 10IR absorptive    3211      3231      3251    3271layer 11IR absorptive    3212      3232      3252    3272layer 12IR absorptive    3213      3233      3253    3273layer 13IR absorptive    3214      3234      3254    3274layer 14IR absorptive    3215      3235      3255    3275layer 15IR absorptive    3216      3236      3256    3276layer 16IR absorptive    3217      3237      3257    3277layer 17IR absorptive    3218      3238      3258    3278layer 18IR absorptive    3219      3239      3259    3279layer 19IR absorptive    3220      3240      3260    3280layer 20______________________________________ 
    
     
                       TABLE 54______________________________________              Substrate             Layer  Gas used and its              temper-  RF    Inner  thick-Name of  flow rate   ature    power pressure                                    nesslayer  (SCCM)      (°C.)                       (W)   (Torr) (μm)______________________________________Contact  SiH.sub.4          20      250    50    0.05   0.5layer 6  NO       2Contact  SiH.sub.4          20      250    50    0.05   0.5layer 7  CH.sub.4          40  H.sub.2 50Contact  SiH.sub.4          10      250    50    0.05   0.5layer 8  SiF.sub.4          10  NO       4  N.sub.2  4  CH.sub.4           6______________________________________ 
    
     
                                           TABLE 55__________________________________________________________________________Contact  Contact         Contact              Contact                   Contact                        Contact                             ContactLayer 1  Layer 2         Layer 3              Layer 4                   Layer 6                        Layer 7                             Layer 8__________________________________________________________________________Drum    3301 3302 3303 3304 3305 3306 3307No.__________________________________________________________________________ 
    
     
                                           TABLE 56__________________________________________________________________________                Substrate    Inner                                  LayerName ofGas used and its                temperature                       RF power                             pressure                                  thicknesslayerflow rate (SCCM)                (°C.)                       (W)   (Torr)                                  (μm)__________________________________________________________________________ChargeSiH.sub.4 100   250    150   0.35 3injectionH.sub.2   100inhibitionB.sub.2 H.sub.6 (against SiH.sub.4)          1000             ppmlayer 2GeH.sub.4 10NO        10ChargeSiH.sub.4 80 250                170    0.25  3injectionSiF.sub.4 20inhibitionB.sub.2 H.sub.6 (against SiH.sub.4)          1000             ppmlayer 3SnH.sub.4 5NO        5ChargeSiH.sub.4 100             250                150    0.35  3injectionH.sub.2   100inhibitionB.sub.2 H.sub.6 (against SiH.sub.4)          1000             ppmlayer 7NO*       10NO**           10 → 0***__________________________________________________________________________ *substrate side 2 μm **surface layer side 2 μm ***constantly changed 
    
     
                       TABLE 57______________________________________              Substrate             Layer  Gas used and its              temper-  RF    Inner  thick-Name of  flow rate   ature    power pressure                                    nesslayer  (SCCM)      (°C.)                       (W)   (Torr) (μm)______________________________________Contact  SiH.sub.4          20      250    50    0.05   0.5layer 5  N.sub.2 10Contact  SiH.sub.4          20      250    50    0.05   0.5layer 6  NO       2Contact  SiH.sub.4          20      250    50    0.05   0.5layer 7  CH.sub.4          40  H.sub.2 50Contact  SiH.sub.4          10      250    50    0.05   0.5layer 8  SiF.sub.4          10  NO       4  N.sub.2  4  CH.sub.4           6______________________________________ 
    
     
                                           TABLE 58__________________________________________________________________________   Charge        Charge             Charge                  Charge                       Charge                            Charge   injection        injection             injection                  injection                       injection                            injection   inhibition        inhibition             inhibition                  inhibition                       inhibition                            inhibitionDrum No.   layer 2        layer 3             layer 4                  layer 5                       layer 6                            layer 7__________________________________________________________________________Contact layer 1   3401 3409 3417 3425 3433 3441Contact layer 2   3402 3410 3418 3426 3434 3442Contact layer 3   3403 3411 3419 3427 3435 3443Contact layer 4   3404 3412 3420 3428 3436 3444Contact layer 5   3405 3413 3421 3429 3437 3445Contact layer 6   3406 3414 3422 3430 3438 3446Contact layer 7   3407 3415 3423 3431 3439 3447Contact layer 8   3408 3416 3424 3432 3440 3448__________________________________________________________________________ 
    
     
                                           TABLE 59__________________________________________________________________________Charge     Charge          Charge               Charge                    Charge                         Charge                              Chargeinjection     injection          injection               injection                    injection                         injection                              injectionDrum inhibition     inhibition          inhibition               inhibition                    inhibition                         inhibitionNo.  layer 1     layer 2          layer 3               layer 4                    layer 5                         layer 6                              layer 7__________________________________________________________________________Contact3501 3509 3517 3525 3533 3541 3549layer 1Contact3502 3510 3518 3526 3534 3542 3550layer 2Contact3503 3511 3519 3527 3535 3543 3551layer 3Contact3504 3512 3520 3528 3536 3544 3552layer 4Contact3505 3513 3521 3529 3537 3545 3553layer 5Contact3506 3514 3522 3530 3538 3546 3554layer 6Contact3507 3515 3523 3531 3539 3547 3555layer 7Contact3508 3516 3524 3532 3540 3548 3556layer 8__________________________________________________________________________ 
    
     
                                           TABLE 60__________________________________________________________________________Charge     Charge          Charge               Charge                    Charge                         Charge                              Chargeinjection     injection          injection               injection                    injection                         injection                              injectionDrum inhibition     inhibition          inhibition               inhibition                    inhibition                         inhibition                              inhibitionNo.  layer 1     layer 2          layer 3               layer 4                    layer 5                         layer 6                              layer 7__________________________________________________________________________Contact3601 3609 3617 3625 3633 3641 3649layer 1Contact3602 3610 3618 3626 3634 3642 3650layer 2Contact3603 3611 3619 3627 3635 3643 3651layer 3Contact3604 3612 3620 3628 3636 3644 3652layer 4Contact3605 3613 3621 3629 3637 3645 3653layer 5Contact3606 3614 3622 3630 3638 3646 3654layer 6Contact3607 3615 3623 3631 3639 3647 3655layer 7Contact3608 3616 3624 3632 3640 3648 3656layer 8__________________________________________________________________________ 
    
     
                                           TABLE 61__________________________________________________________________________                Substrate    Inner                                  LayerName ofGas used and its                temperature                       RF power                             pressure                                  thicknesslayerflow rate (SCCM)                (°C.)                       (W)   (Torr)                                  (μm)__________________________________________________________________________ChargeSiH.sub.4 100   250    130   0.25 3injectionB.sub.2 H.sub.6 (against SiH.sub.4)          800             ppminhibitionNO        4layer 4N.sub.2   4CH.sub.4  6ChargeSiH.sub.4 100             250                130    0.25  3injectionPH.sub.3 (against SiH.sub.4)          800             ppminhibitionGeH.sub.4 10layer 6NO        10ChargeSiH.sub.4 100             250                150    0.35  3injectionH.sub.2   100inhibitionB.sub.2 H.sub.6 (against SiH.sub.4)          1000             ppmlayer 7NO*       10NO**           10 → 0***__________________________________________________________________________ *substrate side 2 μm **surface layer side 2 μm ***constantly changed 
    
     
                       TABLE 62______________________________________Charge injection          Charge injection                       Charge injectioninhibition layer 4          inhibition layer 6                       inhibition layer 7______________________________________Drum  3701         3702         3703No.______________________________________ 
    
     
                       TABLE 63______________________________________              Substrate             Layer   Gas used and              temper-  RF    Inner  thick-Name of its flow rate              ature    power pressure                                    nesslayer   (SCCM)     (°C.)                       (W)   (Torr) (μm)______________________________________Photo-  SiH.sub.4           200    250    250   0.40   20conductive   Ar      200layer 5Photo-  SiH.sub.4           150    250    350   0.40   20conductive   SiF.sub.4            50layer 6 H.sub.2 200______________________________________ 
    
     
                                           TABLE 64__________________________________________________________________________                Substrate    Inner                                  LayerName ofGas used and its                temperature                       RF power                             pressure                                  thicknesslayerflow rate (SCCM)                (°C.)                       (W)   (Torr)                                  (μm)__________________________________________________________________________ChargeSiH.sub.4 100   250    150   0.35 3injectionH.sub.2   100inhibitionB.sub.2 H.sub.6 (against SiH.sub.4)          1000             ppmlayer 1NO        10ChargeSiH.sub.4 100             250                130    0.25  3injectionB.sub.2 H.sub.6 (against SiH.sub.4)          800             ppminhibitionNO        4layer 4N.sub.2   4CH.sub.4  6ChargeSiH.sub.4 100             250                130    0.25  3injectionPH.sub.3 (against SiH.sub.4)          800             ppminhibitionGeH.sub.4 10layer 6NO        10ChargeSiH.sub.4 100             250                150    0.35  3injectionH.sub.2   100inhibitionB.sub.2 H.sub.6 (against SiH.sub.4)          1000             ppmlayer 7NO*       10NO**           10 → 0***__________________________________________________________________________ *substrate side 2 μm **surface layer side 2 μm ***constantly changed 
    
     
                       TABLE 65______________________________________    Charge    Charge    Charge  Charge    injection injection injection                                injectionDrum     inhibition              inhibition                        inhibition                                inhibitionNo.      layer 1   layer 4   layer 6 layer 7______________________________________Photo-   3801      3803      3805    3807conductivelayer 5Photo-   3802      3804      3806    3808conductivelayer 6______________________________________ 
    
     
                       TABLE 66______________________________________              Substrate             Layer   Gas used and              temper-  RF    Inner  thick-Name of its flow rate              ature    power pressure                                    nesslayer   (SCCM)     (°C.)                       (W)   (Torr) (μm)______________________________________Photo-  SiH.sub.4           200    250    300   0.40   20conductive   H.sub.2 200layer 4Photo-  SiH.sub.4           200    250    250   0.40   20conductive   Ar      200layer 5Photo-  SiH.sub.4           150    250    350   0.40   20conductive   SiF.sub.4            50layer 6 H.sub.2 200______________________________________ 
    
     
                       TABLE 67______________________________________    Charge   Charge     Charge Charge    injection             injection  injection                               injectionDrum     inhibition             inhibition inhibition                               inhibitionNo.      layer 1  layer 4    layer 6                               layer 7______________________________________Photo-   3901     3904       3907   3910conductivelayer 4Photo-   3902     3905       3908   3911conductivelayer 5Photo-   3903     3906       3909   3912conductivelayer 6______________________________________ 
    
     
         ______________________________________    Charge   Charge     Charge Charge    injection             injection  injection                               injectionDrum     inhibition             inhibition inhibition                               inhibitionNo.      layer 1  layer 4    layer 6                               layer 7______________________________________Photo-   4001     4004       4007   4010conductivelayer 4Photo-   4002     4005       4008   4011conductivelayer 5Photo-   4003     4006       4009   4012conductivelayer 6______________________________________ 
    
     
                                           TABLE 70__________________________________________________________________________Gas used and its           Substrate    Inner                             LayerName offlow rate  temperature                  RF power                        pressure                             thicknesslayer(SCCM)     (°C.)                  (W)   (Torr)                             (μm)__________________________________________________________________________SurfaceB.sub.2 H.sub.6 /Ar (20%)        500           250    200   0.35 0.5layer 1NH.sub.3        100__________________________________________________________________________ 
    
     
                                           TABLE 69__________________________________________________________________________ Gas used and its         Substrate    Inner                           LayerName of flow rate         temperature                RF power                      pressure                           thicknesslayer (SCCM)  (°C.)                (W)   (Torr)                           (μm)__________________________________________________________________________Photo- SiH.sub.4     200 250    250   0.40 20conductive Ar  200layer__________________________________________________________________________ 
    
     
                       TABLE 71______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    4101      4121      4141    4161layer 1IR absorptive    4102      4122      4142    4162layer 2IR absorptive    4103      4123      4143    4163layer 3IR absorptive    4104      4124      4144    4164layer 4IR absorptive    4105      4125      4145    4165layer 5IR absorptive    4106      4126      4146    4166layer 6IR absorptive    4107      4127      4147    4167layer 7IR absorptive    4108      4128      4148    4168layer 8IR absorptive    4109      4129      4149    4169layer 9IR absorptive    4110      4130      4150    4170layer 10IR absorptive    4111      4131      4151    4171layer 11IR absorptive    4112      4132      4152    4172layer 12IR absorptive    4113      4133      4153    4173layer 13IR absorptive    4114      4134      4154    4174layer 14IR absorptive    4115      4135      4155    4175layer 15IR absorptive    4116      4136      4156    4176layer 16IR absorptive    4117      4137      4157    4177layer 17IR absorptive    4118      4138      4158    4178layer 18IR absorptive    4119      4139      4159    4179layer 19IR absorptive    4120      4140      4160    4180layer 20______________________________________ 
    
     
                                           TABLE 72__________________________________________________________________________ Gas used and its         Substrate    Inner                           LayerName of flow rate         temperature                RF power                      pressure                           thicknesslayer (SCCM)  (°C.)                (W)   (Torr)                           (μm)__________________________________________________________________________Photo- SiH.sub.4     150 250    350   0.40 20conductive SiF.sub.4      50layer H.sub.2     200__________________________________________________________________________ 
    
     
                       TABLE 73______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    4201      4221      4241    4261layer 1IR absorptive    4202      4222      4242    4262layer 2IR absorptive    4203      4223      4243    4263layer 3IR absorptive    4204      4224      4244    4264layer 4IR absorptive    4205      4225      4245    4265layer 5IR absorptive    4206      4226      4246    4266layer 6IR absorptive    4207      4227      4247    4267layer 7IR absorptive    4208      4228      4248    4268layer 8IR absorptive    4209      4229      4249    4269layer 9IR absorptive    4210      4230      4250    4270layer 10IR absorptive    4211      4231      4251    4271layer 11IR absorptive    4212      4232      4252    4272layer 12IR absorptive    4213      4233      4253    4273layer 13IR absorptive    4214      4234      4254    4274layer 14IR absorptive    4215      4235      4255    4275layer 15IR absorptive    4216      4236      4256    4276layer 16IR absorptive    4217      4237      4257    4277layer 17IR absorptive    4218      4238      4258    4278layer 18IR absorptive    4219      4239      4259    4279layer 19IR absorptive    4220      4240      4260    4280layer 20______________________________________ 
    
     
                       TABLE 74______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    4301      4321      4341    4361layer 1IR absorptive    4302      4322      4342    4362layer 2IR absorptive    4303      4323      4343    4363layer 3IR absorptive    4304      4324      4344    4364layer 4IR absorptive    4305      4325      4345    4365layer 5IR absorptive    4306      4326      4346    4366layer 6IR absorptive    4307      4327      4347    4367layer 7IR absorptive    4308      4328      4348    4368layer 8IR absorptive    4309      4329      4349    4369layer 9IR absorptive    4310      4330      4350    4370layer 10IR absorptive    4311      4331      4351    4371layer 11IR absorptive    4312      4332      4352    4372layer 12IR absorptive    4313      4333      4353    4373layer 13IR absorptive    4314      4334      4354    4374layer 14IR absorptive    4315      4335      4355    4375layer 15IR absorptive    4316      4336      4356    4376layer 16IR absorptive    4317      4337      4357    4377layer 17IR absorptive    4318      4338      4358    4378layer 18IR absorptive    4319      4339      4359    4379layer 19IR absorptive    4320      4340      4360    4380layer 20______________________________________ 
    
     
                       TABLE 75______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    4401      4421      4441    4461layer 1IR absorptive    4402      4422      4442    4462layer 2IR absorptive    4403      4423      4443    4463layer 3IR absorptive    4404      4424      4444    4464layer 4IR absorptive    4405      4425      4445    4465layer 5IR absorptive    4406      4426      4446    4466layer 6IR absorptive    4407      4427      4447    4467layer 7IR absorptive    4408      4428      4448    4468layer 8IR absorptive    4409      4429      4449    4469layer 9IR absorptive    4410      4430      4450    4470layer 10IR absorptive    4411      4431      4451    4471layer 11IR absorptive    4412      4432      4452    4472layer 12IR absorptive    4413      4433      4453    4473layer 13IR absorptive    4414      4434      4454    4474layer 14IR absorptive    4415      4435      4455    4475layer 15IR absorptive    4416      4436      4456    4476layer 16IR absorptive    4417      4437      4457    4477layer 17IR absorptive    4418      4438      4458    4478layer 18IR absorptive    4419      4439      4459    4479layer 19IR absorptive    4420      4440      4460    4480layer 20______________________________________ 
    
     
                       TABLE 76______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    4501      4521      4541    4561layer 1IR absorptive    4502      4522      4542    4562layer 2IR absorptive    4503      4523      4543    4563layer 3IR absorptive    4504      4524      4544    4564layer 4IR absorptive    4505      4525      4545    4565layer 5IR absorptive    4506      4526      4546    4566layer 6IR absorptive    4507      4527      4547    4567layer 7IR absorptive    4508      4528      4548    4568layer 8IR absorptive    4509      4529      4549    4569layer 9IR absorptive    4510      4530      4550    4570layer 10IR absorptive    4511      4531      4551    4571layer 11IR absorptive    4512      4532      4552    4572layer 12IR absorptive    4513      4533      4553    4573layer 13IR absorptive    4514      4534      4554    4574layer 14IR absorptive    4515      4535      4555    4575layer 15IR absorptive    4516      4536      4556    4576layer 16IR absorptive    4517      4537      4557    4577layer 17IR absorptive    4518      4538      4558    4578layer 18IR absorptive    4519      4539      4559    4579layer 19IR absorptive    4520      4540      4560    4580layer 20______________________________________ 
    
     
                       TABLE 77______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    4601      4621      4641    4661layer 1IR absorptive    4602      4622      4642    4662layer 2IR absorptive    4603      4623      4643    4663layer 3IR absorptive    4604      4624      4644    4664layer 4IR absorptive    4605      4625      4645    4665layer 5IR absorptive    4606      4626      4646    4666layer 6IR absorptive    4607      4627      4647    4667layer 7IR absorptive    4608      4628      4648    4668layer 8IR absorptive    4609      4629      4649    4669layer 9IR absorptive    4610      4630      4650    4670layer 10IR absorptive    4611      4631      4651    4671layer 11IR absorptive    4612      4632      4652    4672layer 12IR absorptive    4613      4633      4653    4673layer 13IR absorptive    4614      4634      4654    4674layer 14IR absorptive    4615      4635      4655    4675layer 15IR absorptive    4616      4636      4656    4676layer 16IR absorptive    4617      4637      4657    4677layer 17IR absorptive    4618      4638      4658    4678layer 18IR absorptive    4619      4639      4659    4679layer 19IR absorptive    4620      4640      4660    4680layer 20______________________________________ 
    
     
                                           TABLE 78__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Charge SiH.sub.4 100   250    150   0.35  3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppmlayer NO        10Photo- SiH.sub.4 200   250    350   0.35 20conductive He        200layer__________________________________________________________________________ 
    
     
                                           TABLE 79__________________________________________________________________________    Gas used and its            Substrate    Inner                              LayerDrum    flow rate    temperature                   RF power                         pressure                              thicknessNo. (SCCM)       (°C.)                   (W)   (Torr)                              (μm)__________________________________________________________________________4701    B.sub.2 H.sub.6 /Ar (20%)       500  250    200   0.35 0.5    NH.sub.3       1004702    B.sub.2 H.sub.6 /Ar (20%)       500  250    200   0.40 0.5    H.sub.2 100    NH.sub.3       1004703    B.sub.2 H.sub.6 /Ar (20%)       500  250    200   0.35 0.5    NH.sub.3       100    Bias voltage of       150          V    the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 80__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________IR    SiH.sub.4 100   250    150   0.35 1absorptive H.sub.2   100layer GeH.sub.4 50 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm NO        10Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppmlayer NO        10Photo- SiH.sub.4 200   250    350   0.35 20conductive He        200layer__________________________________________________________________________ 
    
     
                                           TABLE 81__________________________________________________________________________    Gas used and its             Substrate    Inner                               LayerDrum    flow rate     temperature                    RF power                          pressure                               thicknessNo. (SCCM)        (°C.)                    (W)   (Torr)                               (μm)__________________________________________________________________________4801    B.sub.2 H.sub.6 /Ar (20%)       500   250    200   0.35 0.5    NH.sub.3       1004802    B.sub.2 H.sub.6 /Ar (20%)       500   250    200   0.40 0.5    H.sub.2 100    NH.sub.3       1004803    B.sub.2 H.sub.6 /Ar (20%)       500   250    200   0.35 0.5    NH.sub.3       100    Bias voltage of       -150           V    the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 82__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Contact SiH.sub.4 20    250     50   0.05 0.5layer N.sub.2   10IR    SiH.sub.4 100   250    150   0.35 1absorptive H.sub.2   100layer GeH.sub.4 50 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm NO        10Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppmlayer NO        10Photo- SiH.sub.4 200   250    350   0.35 20conductive He        200layer__________________________________________________________________________ 
    
     
                                           TABLE 83__________________________________________________________________________    Gas used and its             Substrate    Inner                               LayerDrum    flow rate     temperature                    RF power                          pressure                               thicknessNo. (SCCM)        (°C.)                    (W)   (Torr)                               (μm)__________________________________________________________________________4901    B.sub.2 H.sub.6 /Ar (20%)       500   250    200   0.35 0.5    NH.sub.3       1004902    B.sub.2 H.sub.6 /Ar (20%)       500   250    200   0.40 0.5    H.sub.2 100    NH.sub.3       1004903    B.sub.2 H.sub.6 /Ar (20%)       500   250    200   0.35 0.5    NH.sub.3       100    Bias voltage of       -150           V    the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 84__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppmlayer NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerInter- SiH.sub.4 10    250    150   0.35 0.3mediate CH.sub.4  400layerSurface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.35 0.5layer NH.sub.3  100__________________________________________________________________________ 
    
     
                       TABLE 85______________________________________Drum No.  5101      5102   5103    5104 5105______________________________________a (μm) 25        50     50      12   12b (μm) 0.8       2.5    0.8     1.5  0.3______________________________________ 
    
     
                       TABLE 86______________________________________Drum No.  5201      5202   5203    5204 5205______________________________________c (μm) 50        100    100     30   30d (μm) 1.2       5      0.9     2.5  0.4______________________________________ 
    
     
                                           TALBE 87__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Photo- SiH.sub.4 200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)           100              ppmlayer NO        4Surface B.sub.2 H.sub.6 /He (20%)           500   250    100   0.35 0.5layer NH.sub.3  100__________________________________________________________________________ 
    
     
                       TABLE 88______________________________________Intial                                  Increaseelectri-fication  Residual          Defective                            Image  defectiveefficiency  voltage   Ghost   image   flow   image______________________________________○  ○  ○                    ⊚                            ⊚                                   ○______________________________________                       Degree of                                Degree ofSurface  Break down  Abrasion background                                residualabrasion  voltage     resistance                       fogginess                                stress______________________________________○  ○    ○ ⊚                                ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 89__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Photo- SiH.sub.4 200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)           100              ppmlayer NO        4Surface B.sub.2 H.sub.6 /He (20%)           500   250    100   0.40 0.5layer H.sub.2   100 NH.sub.3  300__________________________________________________________________________ 
    
     
                       TABLE 90______________________________________Initial                                 Increaseelectri-                                offication  Residual          Defective                            Image  defectiveefficiency  voltage  Ghost    image   flow   image______________________________________○   ○           ○ ⊚                            ⊚                                   ○______________________________________   Break              Degree of                               Degree ofSurface down     Abrasion  background                               residualabrasion   voltage  resistance                      fogginess                               stress______________________________________○   ○ ○  ⊚                               ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                       TABLE 91______________________________________Initial                                 Increaseelectri-                                offication  Residual          Defective                            Image  defectiveefficiency  voltage   Ghost   image   flow   image______________________________________○  ○  ○                    ⊚                            ⊚                                   ○______________________________________   Break              Degree of                               Degree ofSurface down     Abrasion  background                               residualabrasion   voltage  resistance                      fogginess                               stress______________________________________○   ○ ○  ⊚                               ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 92__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppmlayer NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /He (20%)           500   250    100   0.35 0.5layer NH.sub.3  100__________________________________________________________________________ 
    
     
                       TABLE 93______________________________________Initial                                 Increaseelectri-                                offication  Residual          Defective                            Image  defectiveefficiency  voltage  Ghost    image   flow   image______________________________________⊚  ○ ○ ⊚                            ⊚                                   ○______________________________________   Break              Degree of                               Degree ofSurface down     Abrasion  background                               residualabrasion   voltage  resistance                      fogginess                               stress______________________________________○   ○ ○  ⊚                               ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 94__________________________________________________________________________ Gas used and its            Substrate    Inner                              LayerName of flow rate  temperature                   RF power                         pressure                              thicknesslayer (SCCM)     (°C.)                   (W)   (Torr)                              (μm)__________________________________________________________________________Photo- SiH.sub.4         200            250    300   0.40 20conductive H.sub.2 200layerSurface B.sub.2 H.sub.6 /He (20%)         500            250    100   0.35 0.5layer NH.sub.3         100__________________________________________________________________________ 
    
     
                       TABLE 95______________________________________Initial                                 Increaseelectri-                                offication  Residual          Defective                            Image  defectiveefficiency  voltage  Ghost    image   flow   image______________________________________⊚  ○ ○ ⊚                            ⊚                                   ○______________________________________   Break              Degree of                               Degree ofSurface down     Abrasion  background                               residualabrasion   voltage  resistance                      fogginess                               stress______________________________________○   ○ ○  ⊚                               ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 96__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________IR    SiH.sub.4 100   250    150   0.35 1absorptive H.sub.2   100layer GeH.sub.4 50 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /He (20%)           500   250    100   0.35 0.5layer NH.sub.3  100__________________________________________________________________________ 
    
     
                       TABLE 97______________________________________Initial                                 Increaseelectri-                                offication  Residual          Defective                            Image  defectiveefficiency  voltage  Ghost    image   flow   image______________________________________○  ○ ○ ⊚                            ⊚                                   ○______________________________________  Break            Inter- Degree of                                  Degree ofSurface  down    Abrasion ference                          background                                  residualabrasion  voltage resistance                   fringe fogginess                                  stress______________________________________○  ○          ○ ○                          ⊚                                  ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 98__________________________________________________________________________ Gas used and its            Substrate    Inner                              LayerName of flow rate  temperature                   RF power                         pressure                              thicknesslayer (SCCM)     (°C.)                   (W)   (Torr)                              (μm)__________________________________________________________________________Contact SiH.sub.4          20            250    100   0.25 0.5layer N.sub.2 100Photo- SiH.sub.4         200            250    300   0.40 20conductive H.sub.2 200layerSurface B.sub.2 H.sub.6 /He (20%)         500            250    100   0.35 0.5layer NH.sub.3         100__________________________________________________________________________ 
    
     
                       TABLE 99______________________________________Initial                                 Increaseelectri-                                offication  Residual          Defective                            Image  defectiveefficiency  voltage  Ghost    image   flow   image______________________________________⊚  ○ ○ ⊚                            ⊚                                   ○______________________________________   Break              Degree of                               Degree ofSurface down     Abrasion  background                               residualabrasion   voltage  resistance                      fogginess                               stress______________________________________○   ○ ○  ⊚                               ○______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 100__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________IR    SiH.sub.4 100   250    150   0.35 1absorptive H.sub.2   100layer GeH.sub.4 50 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm NO        10Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppmlayer NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /He (20%)           500   250    100   0.35 0.5layer NH.sub.3  100__________________________________________________________________________ 
    
     
                       TABLE 101______________________________________Initial                                 Increaseelectri-                                offication  Residual          Defective                            Image  defectiveefficiency  voltage  Ghost    image   flow   image______________________________________⊚  ○ ○ ⊚                            ⊚                                   ○______________________________________  Break            Inter- Degree of                                  Degree ofSurface  down    Abrasion ference                          background                                  residualabrasion  voltage resistance                   fringe fogginess                                  stress______________________________________○  ○          ○  ○                          ⊚                                  ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 102__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Contact SiH.sub.4 20    250     50   0.05 0.5layer N.sub.2   10Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppmlayer NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /He (20%)           500   250    100   0.35 0.5layer NH.sub.3  100__________________________________________________________________________ 
    
     
                       TABLE 103______________________________________Initial                                 Increaseelectri-                                offication  Residual          Defective                            Image  defectiveefficiency  voltage  Ghost    image   flow   image______________________________________⊚  ○ ○ ⊚                            ⊚                                   ○______________________________________   Break              Degree of                               Degree ofSurface down     Abrasion  background                               residualabrasion   voltage  resistance                      fogginess                               stress______________________________________○   ○ ○  ⊚                               ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 104__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Contact SiH.sub.4 20    250    50    0.05 0.5layer N.sub.2   10IR    SiH.sub.4 100   250    150   0.35 1absorptive H.sub.2   100layer GeH.sub.4 50 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm NO        10Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppmlayer NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.3 H.sub.6 /He (20%)           500   250    100   0.35 0.5layer NH.sub.3  100__________________________________________________________________________ 
    
     
                                           TABLE 105__________________________________________________________________________Initial electrification      Residual   Defective                        Image                             Increase ofefficiency voltage            Ghost                 image  flow defective image__________________________________________________________________________⊚      ○            ○                 ⊚                        ⊚                             ○__________________________________________________________________________SurfaceBreakdown       Abrasion            Interference                   Degree of background                              Degree ofabrasionvoltage       resistance            fringe fogginess  residual stress__________________________________________________________________________○○       ○            ○                   ⊚                              ⊚__________________________________________________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 106__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5                          layer 6                               layer 7__________________________________________________________________________Photo- 6701 6706 6711 6716 6721 6726 6731conductivelayer 1Photo- 6702 6707 6712 6717 6722 6727 6732conductivelayer 2Photo- 6703 6708 6713 6718 6723 6728 6733conductivelayer 3Photo- 6704 6709 6714 6719 6724 6729 6734conductivelayer 5Photo- 6705 6710 6715 6720 6725 6730 6735conductivelayer 6__________________________________________________________________________ 
    
     
                                           TABLE 107__________________________________________________________________________Gas used and its           Substrate    Inner                             LayerName offlow rate  temperature                  RF power                        pressure                             thicknesslayer(SCCM)     (°C.)                  (W)   (Torr)                             (μm)__________________________________________________________________________SurfaceB.sub.2 H.sub.6 /He (20%)        500           250    100   0.40 0.5layerH.sub.2 100NH.sub.3        300__________________________________________________________________________ 
    
     
                                           TABLE 108__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5                          layer 6                               layer 7__________________________________________________________________________Photo- 6801 6807 6813 6819 6825 6831 6837conductivelayer 1Photo- 6802 6808 6814 6820 6826 6832 6838conductivelayer 2Photo- 6803 6809 6815 6821 6827 6833 6839conductivelayer 3Photo- 6804 6810 6816 6822 6828 6834 6840conductivelayer 4Photo- 6805 6811 6817 6823 6829 6835 6841conductivelayer 5Photo- 6806 6812 6818 6824 6830 6836 6842conductivelayer 6__________________________________________________________________________ 
    
     
                                           TABLE 109__________________________________________________________________________Gas used and its              Substrate    Inner                                LayerName offlow rate     temperature                     Rf power                           pressure                                thicknesslayer(SCCM)        (°C.)                     (W)   (Torr)                                (μm)__________________________________________________________________________SurfaceB.sub.2 H.sub.6 /He (20%)        500   250    100   0.35 0.5layerNH.sub.3        100Bias voltage ofthe cylinder        +150            V__________________________________________________________________________ 
    
     
                                           TABLE 110__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5                          layer 6                               layer 7__________________________________________________________________________Photo- 6901 6907 6913 6919 6925 6931 6937conductivelayer 1Photo- 6902 6908 6914 6920 6926 6932 6938conductivelayer 2Photo- 6903 6909 6915 6921 6927 6933 6939conductivelayer 3Photo- 6904 6910 6916 6922 6928 6934 6940conductivelayer 4Photo- 6905 6911 6917 6923 6929 6935 6941conducitvelayer 5Photo- 6906 6912 6918 6924 6930 6936 6942conductivelayer 6__________________________________________________________________________ 
    
     
                                           TABLE 111__________________________________________________________________________Photo-   Photo-          Photo-               Photo-                     Photo-conduc-  conduc-          conduc-               conduc-                     conduc-tive     tive  tive tive  tiveLayer 1  Layer 2          Layer 3               Layer 5                     Layer 6__________________________________________________________________________Drum    7001 7002  7003 7004  7005No.__________________________________________________________________________ 
    
     
                                           TABLE 112__________________________________________________________________________Photo-    Photo-           Photo-                 Photo-                       Photo-                             Photo-layer 1   layer 2           layer 3                 layer 4                       layer 5                             layer 6__________________________________________________________________________Drum    7101  7102  7103  7104  7105  7106No.__________________________________________________________________________ 
    
     
                                           TABLE 113__________________________________________________________________________Photo-    Photo-           Photo-                 Photo-                       Photo-                             Photo-conductive     conductive           conductive                 conductive                       conductive                             conductivelayer 1   layer 2           layer 3                 layer 4                       layer 5                             layer 6__________________________________________________________________________Drum    7201  7202  7203  7204  7205  7206No.__________________________________________________________________________ 
    
     
                       TABLE 114______________________________________         Drum         No.______________________________________IR Absorptive   7301Layer 1IR Absorptive   7302Layer 2IR Absorptive   7303Layer 3IR Absorptive   7304Layer 4IR Absorptive   7305Layer 5IR Absorptive   7306Layer 6IR Absorptive   7307Layer 7IR Absorptive   7308Layer 8IR Absorptive   7309Layer 9IR Absorptive   7310Layer 10IR Absorptive   7311Layer 11IR Absorptive   7312Layer 12IR Absorptive   7313Layer 13IR Absorptive   7314Layer 14IR Absorptive   7315Layer 15IR Absorptive   7316Layer 17IR Absorptive   7317Layer 18IR Absorptive   7318Layer 19IR Absorptive   7319Layer 20______________________________________ 
    
     
                                           TABLE 115__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-Drum   conductive        conductive              conductive                    conductive                          conductiveNo.    layer 1        layer 2              layer 3                    layer 5                          layer 6__________________________________________________________________________IR absorptive  7401  7421  7441  7461  7481layer 1IR absorptive  7402  7422  7442  7462  7482layer 2IR absorptive  7403  7423  7443  7463  7483layer 3IR absorptive  7404  7424  7444  7464  7484layer 4IR absorptive  7405  7425  7445  7465  7485layer 5IR absorptive  7406  7426  7446  7466  7486layer 6IR absorptive  7407  7427  7477  7467  7487layer 7IR absorptive  7408  7428  7448  7468  7488layer 8IR absorptive  7409  7429  7449  7469  7489layer 9IR absorptive  7410  7430  7450  7470  7490layer 10IR absorptive  7411  7431  7451  7471  7491layer 11IR absorptive  7412  7432  7452  7472  7492layer 12IR absorptive  7413  7433  7453  7473  7493layer 13IR absorptive  7414  7434  7454  7474  7494layer 14IR absorptive  7415  7435  7455  7475  7495layer 15IR absorptive  7416  7436  7456  7476  7496layer 16IR absorptive  7417  7437  7457  7477  7497layer 17IR absorptive  7418  7438  7458  7478  7498layer 18IR absorptive  7419  7439  7459  7479  7499layer 19IR absorptive  7420  7440  7460  7480  74100layer 20__________________________________________________________________________ 
    
     
                                           TABLE 116__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-                                Photo-Drum   conductive        conductive              conductive                    conductive                          conductive                                conductiveNo.    layer 1        layer 2              layer 3                    layer 4                          layer 5                                layer 6__________________________________________________________________________IR absorptive  7501  7521  7541  7561  7581  75101layer 1IR absorptive  7502  7522  7542  7562  7582  75102layer 2IR absorptive  7503  7523  7543  7563  7583  75103layer 3IR absorptive  7504  7524  7544  7564  7584  75104layer 4IR absorptive  7505  7525  7545  7565  7585  75105layer 5IR absorptive  7506  7526  7546  7566  7586  75106layer 6IR absorptive  7507  7527  7547  7567  7587  75107layer 7IR absorptive  7508  7528  7548  7568  7588  75108layer 8IR absorptive  7509  7529  7549  7569  7589  75109layer 9IR absorptive  7510  7530  7550  7570  7590  75110layer 10IR absorptive  7511  7531  7551  7571  7591  75111layer 11IR absorptive  7512  7532  7552  7572  7592  75112layer 12IR absorptive  7513  7533  7553  7573  7593  75113layer 13IR absorptive  7514  7534  7554  7574  7594  75114layer 14IR absorptive  7515  7535  7555  7575  7595  75115layer 15IR absorptive  7516  7536  7556  7576  7596  75116layer 16IR absorptive  7517  7537  7557  7577  7597  75117layer 17IR absorptive  7518  7538  7558  7578  7598  75118layer 18IR absorptive  7519  7539  7559  7579  7599  75119layer 19IR absorptive  7520  7540  7560  7580  75100 75120layer 20__________________________________________________________________________ 
    
     
                                           TABLE 117__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-                                Photo-Drum   conductive        conductive              conductive                    conductive                          conductive                                conductiveNo.    layer 1        layer 2              layer 3                    layer 4                          layer 5                                layer 6__________________________________________________________________________IR absorptive  7601  7621  7641  7661  7681  76101layer 1IR absorptive  7602  7622  7642  7662  7682  76102layer 2IR absorptive  7603  7623  7643  7663  7683  76103layer 3IR absorptive  7604  7624  7644  7664  7684  76104layer 4IR absorptive  7605  7625  7645  7665  7685  76105layer 5IR absorptive  7606  7626  7646  7666  7686  76106layer 6IR absorptive  7607  7627  7647  7667  7687  76107layer 7IR absorptive  7608  7628  7648  7668  7688  76108layer 8IR absorptive  7609  7629  7649  7669  7689  76109layer 9IR absorptive  7610  7630  7650  7670  7690  76110layer 10IR absorptive  7611  7631  7651  7671  7691  76111layer 11IR absorptive  7612  7632  7652  7672  7692  76112layer 12IR absorptive  7613  7633  7653  7673  7693  76113layer 13IR absorptive  7614  7634  7654  7674  7694  76114layer 14IR absorptive  7615  7635  7655  7675  7695  76115layer 15IR absorptive  7616  7636  7656  7676  7696  76116layer 16IR absorptive  7617  7637  7657  7677  7697  76117layer 17IR absorptive  7618  7638  7658  7678  7698  76118layer 18IR absorptive  7619  7639  7659  7679  7699  76119layer 19IR absorptive  7620  7640  7660  7680  76100 76120layer 20__________________________________________________________________________ 
    
     
                       TABLE 118______________________________________  Contact    Contact  Contact  Layer 2    Layer 3  Layer 4______________________________________Drum     7701         7702     7703No.______________________________________ 
    
     
                       TABLE 119______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-   7801      7807      7813    7819conductivelayer 1Photo-   7802      7808      7814    7820conductivelayer 2Photo-   7803      7809      7815    7821conductivelayer 3Photo-   7804      7810      7816    7822conductivelayer 4Photo-   7805      7811      7817    7823conductivelayer 5Photo-   7806      7812      7818    7824conductivelayer 6______________________________________ 
    
     
                       TABLE 120______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-   7901      7907      7913    7919conductivelayer 1Photo-   7902      7908      7914    7920conductivelayer 2Photo-   7903      7909      7915    7921conductivelayer 3Photo-   7904      7910      7916    7922conductivelayer 4Photo-   7905      7911      7917    7923conductivelayer 5Photo-   7906      7912      7918    7924conductivelayer 6______________________________________ 
    
     
                       TABLE 121______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-   8001      8007      8013    8019conductivelayer 1Photo-   8002      8008      8014    8020conductivelayer 2Photo-   8003      8009      8015    8021conductivelayer 3Photo-   8004      8010      8016    8022conductivelayer 4Photo-   8005      8011      8017    8023conductivelayer 5Photo-   8006      8012      8018    8024conductivelayer 6______________________________________ 
    
     
                       TABLE 122______________________________________         Drum         No.______________________________________  IR absorptive           8101  layer 1  IR absorptive           8102  layer 2  IR absorptive           8103  layer 3  IR absorptive           8104  layer 4  IR absorptive           8105  layer 5  IR absorptive           8106  layer 6  IR absorptive           8107  layer 7  IR absorptive           8108  layer 8  IR absorptive           8109  layer 9  IR absorptive           8110  layer 10  IR absorptive           8111  layer 11  IR absorptive           8112  layer 12  IR absorptive           8113  layer 13  IR absorptive           8114  layer 14  IR absorptive           8115  layer 15  IR absorptive           8117  layer 17  IR absorptive           8118  layer 18  IR absorptive           8119  layer 19  IR absorptive           8120  layer 20______________________________________ 
    
     
                       TABLE 123______________________________________      Photo-      Photo-    Photo-Drum       conductive  conductive                            conductiveNo.        layer 4     layer 5   layer 7______________________________________IR absorptive      8201        8221      8241layer 1IR absorptive      8202        8222      8242layer 2IR absorptive      8203        8223      8243layer 3IR absorptive      8204        8224      8244layer 4IR absorptive      8205        8225      8245layer 5IR absorptive      8206        8226      8246layer 6IR absorptive      8207        8227      8247layer 7IR absorptive      8208        8228      8248layer 8IR absorptive      8209        8229      8249layer 9IR absorptive      8210        8230      8250layer 10IR absorptive      8211        8231      8251layer 11IR absorptive      8212        8232      8252layer 12IR absorptive      8213        8233      8253layer 13IR absorptive      8214        8234      8254layer 14IR absorptive      8215        8235      8255layer 15IR absorptive      8216        8236      8256layer 16IR absorptive      8217        8237      8257layer 17IR absorptive      8218        8238      8258layer 18IR absorptive      8219        8239      8259layer 19IR absorptive      8220        8240      8260layer 20______________________________________ 
    
     
                       TABLE 124______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    8301      8321      8341    8361layer 1IR absorptive    8302      8322      8342    8362layer 2IR absorptive    8303      8323      8343    8363layer 3IR absorptive    8304      8324      8344    8364layer 4IR absorptive    8305      8325      8345    8365layer 5IR absorptive    8306      8326      8346    8366layer 6IR absorptive    8307      8327      8347    8367layer 7IR absorptive    8308      8328      8348    8368layer 8IR absorptive    8309      8329      8349    8369layer 9IR absorptive    8310      8330      8350    8370layer 10IR absorptive    8311      8331      8351    8371layer 11IR absorptive    8312      8332      8352    8372layer 12IR absorptive    8313      8333      8353    8373layer 13IR absorptive    8314      8334      8354    8374layer 14IR absorptive    8315      8335      8355    8375layer 15IR absorptive    8316      8336      8356    8376layer 16IR absorptive    8317      8337      8357    8377layer 17IR absorptive    8318      8338      8358    8378layer 18IR absorptive    8319      8339      8359    8379layer 19IR absorptive    8320      8340      8360    8380layer 20______________________________________ 
    
     
                       TABLE 125______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    8401      8421      8441    8461layer 1IR absorptive    8402      8422      8442    8462layer 2IR absorptive    8403      8423      8443    8463layer 3IR absorptive    8404      8424      8444    8464layer 4IR absorptive    8405      8425      8445    8465layer 5IR absorptive    8406      8426      8446    8466layer 6IR absorptive    8407      8427      8447    8467layer 7IR absorptive    8408      8428      8448    8468layer 8IR absorptive    8409      8429      8449    8469layer 9IR absorptive    8410      8430      8450    8470layer 10IR absorptive    8411      8431      8451    8471layer 11IR absorptive    8412      8432      8452    8472layer 12IR absorptive    8413      8433      8453    8473layer 13IR absorptive    8414      8434      8454    8474layer 14IR absorptive    8415      8435      8455    8475layer 15IR absorptive    8416      8436      8456    8476layer 16IR absorptive    8417      8437      8457    8477layer 17IR absorptive    8418      8438      8458    8478layer 18IR absorptive    8419      8439      8459    8479layer 19IR absorptive    8420      8440      8460    8480layer 20______________________________________ 
    
     
                                           TABLE 126__________________________________________________________________________Contact  Contact         Contact              Contact                   Contact                        Contact                             ContactLayer 1  Layer 2         Layer 3              Layer 4                   Layer 6                        Layer 7                             Layer 8__________________________________________________________________________Drum    8501 8502 8503 8504 8505 8506 8507No.__________________________________________________________________________ 
    
     
                       TABLE 127______________________________________  Charge  Charge   Charge                         Charge                               Charge Charge  injec-  injec-   injec-                         injec-                               injec- injec-  tion    tion     tion  tion  tion   tion  inhibi- inhibi-  inhibi-                         inhibi-                               inhibi-                                      inhibi-Drum   tion    tion     tion  tion  tion   tionNo.    layer 2 layer 3  layer 4                         layer 5                               layer 6                                      layer 7______________________________________Contact  8601    8609     8617  8625  8633   8641layer 1Contact  8602    8610     8618  8626  8634   8642layer 2Contact  8603    8611     8619  8627  8635   8643layer 3Contact  8604    8612     8620  8628  8636   8644layer 4Contact  8605    8613     8621  8629  8637   8645layer 5Contact  8606    8614     8622  8630  8638   8646layer 6Contact  8607    8615     8623  8631  8639   8647layer 7Contact  8608    8616     8624  8662  8640   8648layer 8______________________________________ 
    
     
                                           TABLE 128__________________________________________________________________________Charge     Charge          Charge               Charge                    Charge                         Charge                              Chargeinjection     injection          injection               injection                    injection                         injection                              injectionDrum inhibition     inhibition          inhibition               inhibition                    inhibition                         inhibition                              inhibitionNo.  layer 1     layer 2          layer 3               layer 4                    layer 5                         layer 6                              layer 7__________________________________________________________________________Contact8701 8709 8717 8725 8733 8741 8749layer 1Contact8702 8710 8718 8726 8734 8742 8750layer 2Contact8703 8711 8719 8727 8735 8743 8751layer 3Contact8704 8712 8720 8728 8736 8744 8752layer 4Contact8705 8713 8721 8729 8737 8745 8753layer 5Contact8706 8714 8722 8730 8738 8746 8754layer 6Contact8707 8715 8723 8731 8739 8747 8755layer 7Contact8708 8716 8724 8732 8740 8748 8756layer 8__________________________________________________________________________ 
    
     
                                           TABLE 129__________________________________________________________________________Charge     Charge          Charge               Charge                    Charge                         Charge                              Chargeinjection     injection          injection               injection                    injection                         injection                              injectionDrum inhibition     inhibition          inhibition               inhibition                    inhibition                         inhibition                              inhibitionNo.  layer 1     layer 2          layer 3               layer 4                    layer 5                         layer 6                              layer 7__________________________________________________________________________Contact8801 8809 8817 8825 8833 8841 8849layer 1Contact8802 8810 8818 8826 8834 8842 8850layer 2Contact8803 8811 8819 8827 8835 8843 8851layer 3Contact8804 8812 8820 8828 8836 8844 8852layer 4Contact8805 8813 8821 8829 8837 8845 8853layer 5Contact8806 8814 8822 8830 8838 8846 8854layer 6Contact8807 8815 8823 8831 8839 8847 8855layer 7Contact8808 8816 8824 8832 8840 8848 8856layer 8__________________________________________________________________________ 
    
     
                       TABLE 130______________________________________Charge            Charge   Chargeinjection         injection                      injectioninhibition        inhibition                      inhibitionlayer 4           layer 6  layer 7______________________________________Drum    8901          8902     8903No.______________________________________ 
    
     
                       TABLE 131______________________________________    Charge    Charge    Charge  Charge    injection injection injection                                injectionDrum     inhibition              inhibition                        inhibition                                inhibitionNo.      layer 1   layer 4   layer 6 layer 7______________________________________Photo-   9001      9003      9005    9007conductivelayer 5Photo-   9002      9004      9006    9008conductivelayer 6______________________________________ 
    
     
                       TABLE 132______________________________________    Charge    Charge    Charge  Charge    injection injection injection                                injectionDrum     inhibition              inhibition                        inhibition                                inhibitionNo.      layer 1   layer 4   layer 6 layer 7______________________________________Photo-   9101      9104      9107    9110conductivelayer 4Photo-   9102      9105      9108    9111conductivelayer 5Photo-   9103      9106      9109    9112conductivelayer 6______________________________________ 
    
     
                       TABLE 133______________________________________    Charge    Charge    Charge  Charge    injection injection injection                                injectionDrum     inhibition              inhibition                        inhibition                                inhibitionNo.      layer 1   layer 4   layer 6 layer 7______________________________________Photo-   9201      9204      9207    9210conductivelayer 4Photo-   9202      9205      9208    9211conductivelayer 5Photo-   9203      9206      9209    9212conductivelayer 6______________________________________ 
    
     
                                           TABLE 134__________________________________________________________________________Gas used and its           Substrate    Inner                             LayerName offlow rate  temperature                  RF power                        pressure                             thicknesslayer(SCCM)     (°C.)                  (W)   (Torr)                             (μm)__________________________________________________________________________SurfaceB.sub.2 H.sub.6 /He (20%)        500           250    100   0.35 0.5layer 1NH.sub.3        100__________________________________________________________________________ 
    
     
                       TABLE 135______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    9301      9321      9341    9361layer 1IR absorptive    9302      9322      9342    9362layer 2IR absorptive    9303      9323      9343    9363layer 3IR absorptive    9304      9324      9344    9364layer 4IR absorptive    9305      9325      9345    9365layer 5IR absorptive    9306      9326      9346    9366layer 6IR absorptive    9307      9327      9347    9367layer 7IR absorptive    9308      9328      9348    9368layer 8IR absorptive    9309      9329      9349    9369layer 9IR absorptive    9310      9330      9350    9370layer 10IR absorptive    9311      9331      9351    9371layer 11IR absorptive    9312      9332      9352    9372layer 12IR absorptive    9313      9333      9353    9373layer 13IR absorptive    9314      9334      9354    9374layer 14IR absorptive    9315      9335      9355    9375layer 15IR absorptive    9316      9336      9356    9376layer 16IR absorptive    9317      9337      9357    9377layer 17IR absorptive    9318      9338      9358    9378layer 18IR absorptive    9319      9339      9359    9379layer 19IR absorptive    9320      9340      9360    9380layer 20______________________________________ 
    
     
                       TABLE 136______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    9401      9421      9441    9461layer 1IR absorptive    9402      9422      9442    9462layer 2IR absorptive    9403      9423      9443    9463layer 3IR absorptive    9404      9424      9444    9464layer 4IR absorptive    9405      9425      9445    9465layer 5IR absorptive    9406      9426      9446    9466layer 6IR absorptive    9407      9427      9447    9467layer 7IR absorptive    9408      9428      9448    9468layer 8IR absorptive    9409      9429      9449    9469layer 9IR absorptive    9410      9430      9450    9470layer 10IR absorptive    9411      9431      9451    9471layer 11IR absorptive    9412      9432      9452    9472layer 12IR absorptive    9413      9433      9453    9473layer 13IR absorptive    9414      9434      9454    9474layer 14IR absorptive    9415      9435      9455    9475layer 15IR absorptive    9416      9436      9456    9476layer 16IR absorptive    9417      9437      9457    9477layer 17IR absorptive    9418      9438      9458    9478layer 18IR absorptive    9419      9439      9459    9479layer 19IR absorptive    9420      9440      9460    9480layer 20______________________________________ 
    
     
                       TABLE 137______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    9501      9521      9541    9561layer 1IR absorptive    9502      9522      9542    9562layer 2IR absorptive    9503      9523      9543    9563layer 3IR absorptive    9504      9524      9544    9564layer 4IR absorptive    9505      9525      9545    9565layer 5IR absorptive    9506      9526      9546    9566layer 6IR absorptive    9507      9527      9547    9567layer 7IR absorptive    9508      9528      9548    9568layer 8IR absorptive    9509      9529      9549    9569layer 9IR absorptive    9510      9530      9550    9570layer 10IR absorptive    9511      9531      9551    9571layer 11IR absorptive    9512      9532      9552    9572layer 12IR absorptive    9513      9533      9553    9573layer 13IR absorptive    9514      9534      9554    9574layer 14IR absorptive    9515      9535      9555    9575layer 15IR absorptive    9516      9536      9556    9576layer 16IR absorptive    9517      9537      9557    9577layer 17IR absorptive    9518      9538      9558    9578layer 18IR absorptive    9519      9539      9559    9579layer 19IR absorptive    9520      9540      9560    9580layer 20______________________________________ 
    
     
                       TABLE 138______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    9601      9621      9641    9661layer 1IR absorptive    9602      9622      9642    9662layer 2IR absorptive    9603      9623      9643    9663layer 3IR absorptive    9604      9624      9644    9664layer 4IR absorptive    9605      9625      9645    9665layer 5IR absorptive    9606      9626      9646    9666layer 6IR absorptive    9607      9627      9647    9667layer 7IR absorptive    9608      9628      9648    9668layer 8IR absorptive    9609      9629      9649    9669layer 9IR absorptive    9610      9630      9650    9670layer 10IR absorptive    9611      9631      9651    9671layer 11IR absorptive    9612      9632      9652    9672layer 12IR absorptive    9613      9633      9653    9673layer 13IR absorptive    9614      9634      9654    9674layer 14IR absorptive    9615      9635      9655    9675layer 15IR absorptive    9616      9636      9656    9676layer 16IR absorptive    9617      9637      9657    9677layer 17IR absorptive    9618      9638      9658    9678layer 18IR absorptive    9619      9639      9659    9679layer 19IR absorptive    9620      9640      9660    9680layer 20______________________________________ 
    
     
                       TABLE 139______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    9701      9721      9741    9761layer 1IR absorptive    9702      9722      9742    9762layer 2IR absorptive    9703      9723      9743    9763layer 3IR absorptive    9704      9724      9744    9764layer 4IR absorptive    9705      9725      9745    9765layer 5IR absorptive    9706      9726      9746    9766layer 6IR absorptive    9707      9727      9747    9767layer 7IR absorptive    9708      9728      9748    9768layer 8IR absorptive    9709      9729      9749    9769layer 9IR absorptive    9710      9730      9750    9770layer 10IR absorptive    9711      9731      9751    9771layer 11IR absorptive    9712      9732      9752    9772layer 12IR absorptive    9713      9733      9753    9773layer 13IR absorptive    9714      9734      9754    9774layer 14IR absorptive    9715      9735      9755    9775layer 15IR absorptive    9716      9736      9756    9776layer 16IR absorptive    9717      9737      9757    9777layer 17IR absorptive    9718      9738      9758    9778layer 18IR absorptive    9719      9739      9759    9779layer 19IR absorptive    9720      9740      9760    9780layer 20______________________________________ 
    
     
                       TABLE 140______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    9801      9821      9841    9861layer 1IR absorptive    9802      9822      9842    9862layer 2IR absorptive    9803      9823      9843    9863layer 3IR absorptive    9804      9824      9844    9864layer 4IR absorptive    9805      9825      9845    9865layer 5IR absorptive    9806      9826      9846    9866layer 6IR absorptive    9807      9827      9847    9867layer 7IR absorptive    9808      9828      9848    9868layer 8IR absorptive    9809      9829      9849    9869layer 9IR absorptive    9810      9830      9850    9870layer 10IR absorptive    9811      9831      9851    9871layer 11IR absorptive    9812      9832      9852    9872layer 12IR absorptive    9813      9833      9853    9873layer 13IR absorptive    9814      9834      9854    9874layer 14IR absorptive    9815      9835      9855    9875layer 15IR absorptive    9816      9836      9856    9876layer 16IR absorptive    9817      9837      9857    9877layer 17IR absorptive    9818      9038      9858    9878layer 18IR absorptive    9819      9839      9859    9879layer 19IR absorptive    9820      9840      9860    9880layer 20______________________________________ 
    
     
                                           TABLE 141__________________________________________________________________________    Gas used and its          Substrate    Inner                            LayerDrum    flow rate  temperature                 RF power                       pressure                            thicknessNo. (SCCM)     (°C.)                 (W)   (Torr)                            (μm)__________________________________________________________________________9901    B.sub.2 H.sub.6 /He (20%)       500          250    100   0.35 0.5    NH.sub.3       1009902    B.sub.2 H.sub.6 /He (20%)       500          250    100   0.40 0.5    H.sub.2 100    NH.sub.3       3009903    B.sub.2 H.sub.6 /He (20%)       500          250    100   0.35 0.5    NH.sub.3       100Bias voltage ofthe cylinder +100 V__________________________________________________________________________ 
    
     
                                           TABLE 142__________________________________________________________________________    Gas used and its          Substrate    Inner                            LayerDrum    flow rate  temperature                 RF power                       pressure                            thicknessNo. (SCCM)     (°C.)                 (W)   (Torr)                            (μm)__________________________________________________________________________10001    B.sub.2 H.sub.6 /He (20%)       500          250    100   0.35 0.5    NH.sub.3       10010002    B.sub.2 H.sub.6 /He (20%)       500          250    100   0.40 0.5    H.sub.2 100    NH.sub.3       30010003    B.sub.2 H.sub.6 /He (20%)       500          250    100   0.35 0.5    NH.sub.3       100Bias voltage ofthe cylinder +100 V__________________________________________________________________________ 
    
     
                                           TABLE 143__________________________________________________________________________    Gas used and its          Substrate    Inner                            LayerDrum    flow rate  temperature                 RF power                       pressure                            thicknessNo. (SCCM)     (°C.)                 (W)   (Torr)                            (μm)__________________________________________________________________________10101    B.sub.2 H.sub.6 /He (20%)       500          250    100   0.35 0.5    NH.sub.3       10010102    B.sub.2 H.sub.6 /He (20%)       500          250    100   0.40 0.5    H.sub.2 100    NH.sub.3       30010103    B.sub.2 H.sub.6 /He (20%)       500          250    100   0.35 0.5    NH.sub.3       100Bias voltage ofthe cylinder +100 V__________________________________________________________________________ 
    
     
                                           TABLE 144__________________________________________________________________________ Gas used and its            Substrate    Inner                              LayerName of flow rate  temperature                   RF power                         pressure                              thicknesslayer (SCCM)     (°C.)                   (W)   (Torr)                              (μm)__________________________________________________________________________Charge SiH.sub.4         100            250    150   0.35  3injection H.sub.2 100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)layer 1000 ppm NO       10Photo- SiH.sub.4         200            250    300   0.40 20conductive H.sub.2 200layerInter- SiH.sub.4          10            250    150   0.35 0.3mediate CH.sub.4         400layerSurface B.sub.2 H.sub.6 He (20%)         500            250    100   0.35 0.5layer NH.sub.3         100__________________________________________________________________________ 
    
     
                                           TABLE 145__________________________________________________________________________ Gas used and its            Substrate    Inner                              LayerName of flow rate  temperature                   RF power                         pressure                              thicknesslayer (SCCM)     (°C.)                   (W)   (Torr)                              (μm)__________________________________________________________________________Photo- SiH.sub.4         200            250    250   0.35  20conductive B.sub.2 H.sub.6 (against SiH.sub.4)layer 100 ppm NO       4Surface B.sub.2 H.sub.6 /Ar (20%)         500            250    200   0.35 0.3layer NH.sub.3         100(lowerlayer)Surface B.sub.2 H.sub.6 /He (20%)         500            250    100   0.35 0.3layer NH.sub.3         100(upperlayer)__________________________________________________________________________ 
    
     
                       TABLE 146______________________________________Initialelectri-fication Residual           Defective                                Imageefficiency    voltage   Ghost    image    flow______________________________________○ ○  ○ ⊚                                ⊚______________________________________Increaseof              Break                Degree ofdefective  Surface  down    Abrasion     backgroundimage  abrasion voltage resistance   fogginess______________________________________○  ○ ⊚                   ⊚                                ⊚______________________________________ ⊚: Excellent  ○ : Good Δ: Applicable for practical use X: Poor 
    
     
                                           TABLE 147__________________________________________________________________________ Gas used and its            Substrate    Inner                              LayerName of flow rate  temperature                   RF power                         pressure                              thicknesslayer (SCCM)     (°C.)                   (W)   (Torr)                              (μm)__________________________________________________________________________Photo- SiH.sub.4         200            250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)layer 100 ppm NO       4Surface B.sub.2 H.sub.6 /Ar (20%)         500            250    200   0.40 0.3layer H.sub.2 100(lower NH.sub.3         100layer)Surface B.sub.2 H.sub.6 /He (20%)         500            250    100   0.40 0.3layer H.sub.2 100(upper NH.sub.3         300layer)__________________________________________________________________________ 
    
     
                       TABLE 148______________________________________Initialelectri-fication Residual           Defective                                Imageefficiency    voltage   Ghost    image    flow______________________________________○ ○  ○ ⊚                                ⊚______________________________________Increaseof              Break                Degree ofdefective  Surface  down    Abrasion     backgroundimage  abrasion voltage resistance   fogginess______________________________________○  ○ ⊚                   ⊚                                ⊚______________________________________ ⊚: Excellent  ○ : Good Δ: Applicable for practical use X: Poor 
    
     
                       TABLE 149______________________________________Intial electrification       Residual          Defective                                  Imageefficiency  voltage   Ghost   image    flow______________________________________○    ○  ○                         ⊚                                  ⊚______________________________________                                Degree ofIncrease of     Surface  Breakdown  Abrasion                                backgrounddefective image     abrasion voltage    resistance                                fogginess______________________________________○  ○ ⊚                         ⊚                                ⊚______________________________________ ⊚ Excellent  ○  Good Δ Applicable for practical use X Poor 
    
     
                                           TABLE 150__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)layer           1000              ppm NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.35 0.3layer NH.sub.3  100(lowerlayer)Surface B.sub.2 H.sub.6 /He (20%)           500   250    100   0.35 0.3layer NH.sub.3  100(upperlayer)__________________________________________________________________________ 
    
     
                       TABLE 151______________________________________Intial electrification       Residual          Defective                                  Imageefficiency  voltage   Ghost   image    flow______________________________________⊚       ○  ○                         ⊚                                  ⊚______________________________________                                Degree ofIncrease of     Surface  Breakdown  Abrasion                                backgrounddefective image     abrasion voltage    resistance                                fogginess______________________________________○  ○ ⊚                         ⊚                                ⊚______________________________________ ⊚ Excellent  ○  Good Δ Applicable for practical use X Poor 
    
     
                                           TABLE 152__________________________________________________________________________ Gas used and its            Substrate    Inner                              LayerName of flow rate  temperature                   RF power                         pressure                              thicknesslayer (SCCM)     (°C.)                   (W)   (Torr)                              (μm)__________________________________________________________________________Photo- SiH.sub.4         200            250    300   0.40 20conductive H.sub.2 200layerSurface B.sub.2 H.sub.6 /Ar (20%)         500            250    200   0.35 0.3layer NH.sub.3         100(lowerlayer)Surface B.sub.2 H.sub.6 He (20%)         500            250    100   0.35 0.3layer NH.sub.3         100(upperlayer)__________________________________________________________________________ 
    
     
                       TABLE 153______________________________________Intial electrification       Residual          Defective                                  Imageefficiency  voltage   Ghost   image    flow______________________________________⊚       ○  ○                         ⊚                                  ⊚______________________________________                                Degree ofIncrease of     Surface  Breakdown  Abrasion                                backgrounddefective image     abrasion voltage    resistance                                fogginess______________________________________○  ○ ⊚                         ⊚                                ⊚______________________________________ ⊚ Excellent  ○  Good Δ Applicable for practical use X Poor 
    
     
                                           TABLE 154__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________IR    SiH.sub.4 100   250    150   0.35 1absorptive H.sub.2   100layer GeH.sub.4 50 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.35 0.3layer NH.sub.3  100(lowerlayer)Surface B.sub.2 H.sub.6 /He (20%)           500   250    100   0.35 0.3layer NH.sub.3  100(upperlayer)__________________________________________________________________________ 
    
     
                                           TABLE 155__________________________________________________________________________Intial electrification     Residual Defective                    Image                        Increase ofefficiency     voltage          Ghost              image flow                        defective image__________________________________________________________________________○  ○          ○              ⊚                    ⊚                        ○__________________________________________________________________________Surface Breakdown        Abrasion              Interference                     Degree of backgroundabrasion voltage        resistance              fringe fogginess__________________________________________________________________________○ ⊚        ⊚              ○                     ⊚__________________________________________________________________________ ⊚ Excellent  ○  Good 
    
     
                                           TABLE 156__________________________________________________________________________ Gas used and its            Substrate    Inner                              LayerName of flow rate  temperature                   RF power                         pressure                              thicknesslayer (SCCM)     (°C.)                   (W)   (Torr)                              (μm)__________________________________________________________________________Contact SiH.sub.4          20            250    100   0.25 0.5layer N.sub.2 100Photo- SiH.sub.4         200            250    300   0.40 20conductive H.sub.2 200layerSurface B.sub.2 H.sub.6 /Ar (20%)         500            250    200   0.35 0.3layer NH.sub.3         100(lowerlayer)Surface B.sub.2 H.sub.6 /He (20%)         500            250    100   0.35 0.3layer NH.sub.3         100(upperlayer)__________________________________________________________________________ 
    
     
                       TABLE 157______________________________________Intial electrification       Residual          Defective                                  Imageefficiency  voltage   Ghost   image    flow______________________________________⊚       ○  ○                         ⊚                                  ⊚______________________________________                                Degree ofIncrease of     Surface  Breakdown  Abrasion                                backgrounddefective image     abrasion voltage    resistance                                fogginess______________________________________○  ○ ⊚                         ⊚                                ⊚______________________________________ ⊚ Excellent  ○  Good Δ Applicable for practical use X Poor 
    
     
                                           TABLE 158__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________IR    SiH.sub.4 100   250    150   0.35 1absorptive H.sub.2   100layer GeH.sub.4 50 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm NO        10Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)layer           1000              ppm NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.35 0.3layer NH.sub.3  100(lowerlayer)Surface B.sub.2 H.sub.6 /He (20%)           500   250    100   0.35 0.3layer NH.sub.3  100(upperlayer)__________________________________________________________________________ 
    
     
                                           TABLE 159__________________________________________________________________________Intial electrification     Residual Defective                    Image                        Increase ofefficiency     voltage          Ghost              image flow                        defective image__________________________________________________________________________⊚     ○          ○              ⊚                    ⊚                        ○__________________________________________________________________________Surface Breakdown        Abrasion              Interference                     Degree of backgroundabrasion voltage        resistance              fringe fogginess__________________________________________________________________________○ ⊚        ⊚              ○                     ⊚__________________________________________________________________________ ⊚ Excellent  ○  Good 
    
     
                                           TABLE 160__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Contact SiH.sub.4 20    250     50   0.05 0.5layer N.sub.2   10Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)layer           1000              ppm NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.35 0.3layer NH.sub.3  100(lowerlayer)Surface B.sub.2 H.sub.6 /He (20%)           500   250    100   0.35 0.3layer NH.sub.3  100(upperlayer)__________________________________________________________________________ 
    
     
                       TABLE 161______________________________________Intial electrification       Residual          Defective                                  Imageefficiency  voltage   Ghost   image    flow______________________________________⊚       ○  ○                         ⊚                                  ⊚______________________________________                                Degree ofIncrease of     Surface  Breakdown  Abrasion                                backgrounddefective image     abrasion voltage    resistance                                fogginess______________________________________○  ○ ⊚                         ⊚                                ⊚______________________________________ ⊚ Excellent  ○  Good Δ Applicable for practical use X Poor 
    
     
                                           TABLE 162__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Contact SiH.sub.4 20    250     50   0.05 0.5layer N.sub.2   10IR    SiH.sub.4 100   250    150   0.35 1absorptive H.sub.2   100layer GeH.sub.4 50 B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppm NO        10Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)layer           1000              ppm NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerSurface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.35 0.3layer NH.sub.3  100(lowerlayer)Surface B.sub.2 H.sub.6 /He (20%)           500   250    100   0.35 0.3layer NH.sub.3  100(upperlayer)__________________________________________________________________________ 
    
     
                       TABLE 163______________________________________Initial                                Increaseelectri-                               offication   Residual         Defective                            Image defectiveefficiency   voltage  Ghost   image   flow  image______________________________________⊚   ○ ○                    ⊚                            ⊚                                  ○______________________________________   Break                       Degree ofSurface down     Abrasion  Interference                               backgroundabrasion   voltage  resistance                      fringe   fogginess______________________________________○   ⊚            ⊚                      ○ ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 164__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5                          layer 6                               layer 7__________________________________________________________________________Photo- 11901      11906           11911                11916                     11921                          11926                               11931conductivelayer 1Photo- 11902      11907           11912                11917                     11922                          11927                               11932conductivelayer 2Photo- 11903      11908           11913                11918                     11923                          11928                               11933conductivelayer 3Photo- 11904      11909           11914                11919                     11924                          11929                               11934conductivelayer 5Photo- 11905      11910           11915                11920                     11925                          11930                               11935conductivelayer 6__________________________________________________________________________ 
    
     
                                           TABLE 165__________________________________________________________________________Gas used and its           Substrate    Inner                             LayerName offlow rate  temperature                  RF power                        pressure                             thicknesslayer(SCCM)     (°C.)                  (W)   (Torr)                             (μm)__________________________________________________________________________SurfaceB.sub.2 H.sub.6 /Ar (20%)        500           250    200   0.40 0.3layerH.sub.2 100(lowerNH.sub.3        100layer)SurfaceB.sub.2 H.sub.6 /He (20%)        500           250    100   0.40 0.3layerH.sub.2 100(upperNH.sub.3        300layer)__________________________________________________________________________ 
    
     
                                           TABLE 166__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5                          layer 6                               layer 7__________________________________________________________________________Photo- 12001      12007           12013                12019                     12025                          12031                               12037conductivelayer 1Photo- 12002      12008           12014                12020                     12026                          12032                               12038conductivelayer 2Photo- 12003      12009           12015                12021                     12027                          12033                               12039conductivelayer 3Photo- 12004      12010           12016                12022                     12028                          12034                               12040conductivelayer 4Photo- 12005      12011           12017                12023                     12029                          12035                               12041conductivelayer 5Photo- 12006      12012           12018                12024                     12030                          12036                               12042conductivelayer 6__________________________________________________________________________ 
    
     
                                           TABLE 167__________________________________________________________________________Gas used and its              Substrate    Inner                                LayerName offlow rate     temperature                     RF power                           pressure                                thicknesslayer(SCCM)        (°C.)                     (W)   (Torr)                                (μm)__________________________________________________________________________SurfaceB.sub.2 H.sub.6 /Ar (20%)        500   250    200   0.35 0.3layerNH.sub.3        100(lowerBias voltage of        -150            Vlayer)the cylinderSurfaceB.sub.2 H.sub.6 /He (20%)        500   250    100   0.35 0.3layerNH.sub.3        100(upperBias voltage of        +150            Vlayer)the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 168__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5                          layer 6                               layer 7__________________________________________________________________________Photo- 12101      12107           12113                12119                     12125                          12131                               12137conductivelayer 1Photo- 12102      12108           12114                12120                     12126                          12132                               12138conductivelayer 2Photo- 12103      12109           12115                12121                     12127                          12133                               12139conductivelayer 3Photo- 12104      12110           12116                12122                     12128                          12134                               12140conductivelayer 4Photo- 12105      12111           12117                12123                     12129                          12135                               12141conductivelayer 5Photo- 12106      12112           12118                12124                     12130                          12136                               12142conductivelayer 6__________________________________________________________________________ 
    
     
                       TABLE 169______________________________________Photo-     Photo-    Photo-   Photo-  Photo-con-       con-      con-     con-    con-ductive    ductive   ductive  ductive ductiveLayer 1    Layer 2   Layer 3  Layer 5 Layer 6______________________________________Drum  12201    12202     12203  12204   12205No.______________________________________ 
    
     
                                           TABLE 170__________________________________________________________________________Photo-    Photo-           Photo-                 Photo-                       Photo-                             Photo-conductive     conductive           conductive                 conductive                       conductive                             conductivelayer 1   layer 2           layer 3                 layer 4                       layer 5                             layer 6__________________________________________________________________________Drum    12301 12302 12303 12304 12305 12306No.__________________________________________________________________________ 
    
     
                                           TABLE 171__________________________________________________________________________Photo-    Photo-           Photo-                 Photo-                       Photo-                             Photo-conductive     conductive           conductive                 conductive                       conductive                             conductivelayer 1   layer 2           layer 3                 layer 4                       layer 5                             layer 6__________________________________________________________________________Drum    12401 12402 12403 12404 12405 12406No.__________________________________________________________________________ 
    
     
                       TABLE 172______________________________________         Drum         No.______________________________________IR Absorptive   12501Layer 1IR Absorptive   12502Layer 2IR Absorptive   12503Layer 3IR Absorptive   12504Layer 4IR Absorptive   12505Layer 5IR Absorptive   12506Layer 6IR Absorptive   12507Layer 7IR Absorptive   12508Layer 8IR Absorptive   12509Layer 9IR Absorptive   12510Layer 10IR Absorptive   12511Layer 11IR Absorptive   12512Layer 12IR Absorptive   12513Layer 13IR Absorptive   12514Layer 14IR Absorptive   12515Layer 15IR Absorptive   12516Layer 17IR Absorptive   12517Layer 18IR Absorptive   12518Layer 19IR Absorptive   12519Layer 20______________________________________ 
    
     
                                           TABLE 173__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-Drum   conductive        conductive              conductive                    conductive                          conductiveNo.    layer 1        layer 2              layer 3                    layer 5                          layer 6__________________________________________________________________________IR absorptive  12601 12621 12641 12661 12681layer 1IR absorptive  12602 12622 12642 12662 12682layer 2IR absorptive  12603 12623 12643 12663 12683layer 3IR absorptive  12604 12624 12644 12664 12684layer 4IR absorptive  12605 12625 12645 12665 12685layer 5IR absorptive  12606 12626 12646 12666 12686layer 6IR absorptive  12607 12627 12647 12667 12687layer 7IR absorptive  12608 12628 12648 12668 12688layer 8IR absorptive  12609 12629 12649 12669 12689layer 9IR absorptive  12610 12630 12650 12670 12690layer 10IR absorptive  12611 12631 12651 12671 12691layer 11IR absorptive  12612 12632 12652 12672 12692layer 12IR absorptive  12613 12633 12653 12673 12693layer 13IR absorptive  12614 12634 12654 12674 12694layer 14IR absorptive  12615 12635 12655 12675 12695layer 15IR absorptive  12616 12636 12656 12676 12696layer 16IR absorptive  12617 12637 12657 12677 12697layer 17IR absorptive  12618 12638 12658 12678 12698layer 18IR absorptive  12619 12639 12659 12979 12699layer 19IR absorptive  12620 12640 12660 12680 126100layer 20__________________________________________________________________________ 
    
     
                                           TABLE 174__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-                                Photo-Drum   conductive        conductive              conductive                    conductive                          conductive                                conductiveNo.    layer 1        layer 2              layer 3                    layer 4                          layer 5                                layer 6__________________________________________________________________________IR absorptive  12701 12721 12741 12761 12781 127101layer 1IR absorptive  12702 12722 12742 12762 12782 127102layer 2IR absorptive  12703 12723 12743 12763 12783 127103layer 3IR absorptive  12704 12724 12744 12764 12784 127104layer 4IR absorptive  12705 12725 12745 12765 12785 127105layer 5IR absorptive  12706 12726 12746 12766 12786 127106layer 6IR absorptive  12707 12727 12747 12767 12787 127107layer 7IR absorptive  12708 12728 12748 12768 12788 127108layer 8IR absorptive  12709 12729 12749 12769 12789 127109layer 9IR absorptive  12710 12730 12750 12770 12790 127110layer 10IR absorptive  12711 12731 12751 12771 12791 127111layer 11IR absorptive  12712 12732 12752 12772 12792 127112layer 12IR absorptive  12713 12733 12753 12773 12793 127113layer 13IR absorptive  12714 12734 12754 12774 12794 127114layer 14IR absorptive  12715 12735 12755 12775 12795 127115layer 15IR absorptive  12716 12736 12756 12776 12796 127116layer 16IR absorptive  12717 12737 12757 12777 12797 127117layer 17IR absorptive  12718 12738 12758 12778 12798 127118layer 18IR absorptive  12719 12739 12759 12779 12799 127119layer 19IR absorptive  12720 12740 12760 12780 12700 127120layer 20__________________________________________________________________________ 
    
     
                                           TABLE 175__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-                                Photo-Drum   conductive        conductive              conductive                    conductve                          conductive                                conductiveNo.    layer 1        layer 2              layer 3                    layer 4                          layer 5                                layer 6__________________________________________________________________________IR absorptive  12801 12821 18241 12861 12881 128101layer 1IR absorptive  12802 12822 12842 12862 12882 128102layer 2IR absorptive  12803 12823 12843 12863 12883 128103layer 3IR absorptive  12804 12824 12844 12864 12884 128104layer 4IR absorptive  12805 12825 12845 12865 12885 128105layer 5IR absorptive  12806 12826 12846 12866 12886 128106layer 6IR absorptive  12807 12827 12847 12867 12887 128107layer 7IR absorptive  12808 12828 12848 12868 12888 128108layer 8IR absorptive  12809 12829 12849 12869 12889 128109layer 9IR absorptive  12810 12830 12850 12870 12890 128110layer 10IR absorptive  12811 12831 12851 12871 12891 128111layer 11IR absorptive  12812 12832 12852 12872 12892 128112layer 12IR absorptive  12813 12833 12853 12873 12893 128113layer 13IR absorptive  12814 12834 12854 12874 12894 128114layer 14IR absorptive  12815 12835 12855 12875 12895 128115layer 15IR absorptive  12816 12836 12856 12876 12896 128116layer 16IR absorptive  12817 12837 12857 12877 12897 128117layer 17IR absorptive  12818 12838 12858 12878 12898 128118layer 18IR absorptive  12819 12839 12879 12879 12899 128119layer 19IR absorptive  12820 12840 12860 12880 128100                                128120layer 20__________________________________________________________________________ 
    
     
                       TABLE 176______________________________________Contact           Contact  ContactLayer 2           Layer 3  Layer 4______________________________________Drum    12901         12902    12903No.______________________________________ 
    
     
                       TABLE 177______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-   13001     13007     13013   13019conductivelayer 1Photo-   13002     13008     13014   13020conductivelayer 2Photo-   13003     13009     13015   13021conductivelayer 3Photo-   13004     13010     13016   13022conductivelayer 4Photo-   13005     13011     13017   13023conductivelayer 5Photo-   13006     13012     13018   13024conductivelayer 6______________________________________ 
    
     
                       TABLE 178______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-   13101     13107     13113   13119conductivelayer 1Photo-   13102     13108     13114   13120conductivelayer 2Photo-   13103     13109     13115   13121conductivelayer 3Photo-   13104     13110     13116   13122conductivelayer 4Photo-   13105     13111     13117   13123conductivelayer 5Photo-   13106     13112     13118   13124conductivelayer 6______________________________________ 
    
     
                       TABLE 179______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-   13201     13207     13213   13219conductivelayer 1Photo-   13202     13208     13214   13220conductivelayer 2Photo-   13203     13209     13215   13221conductivelayer 3Photo-   13204     13210     13216   13222conductivelayer 4Photo-   13205     13211     13217   13223conductivelayer 5Photo-   13206     13212     13218   13224conductivelayer 6______________________________________ 
    
     
                       TABLE 180______________________________________         Drum         No.______________________________________  IR absorptive           13301  layer 1  IR absorptive           13302  layer 2  IR absorptive           13303  layer 3  IR absorptive           13304  layer 4  IR absorptive           13305  layer 5  IR absorptive           13306  layer 6  IR absorptive           13307  layer 7  IR absorptive           13308  layer 8  IR absorptive           13309  layer 9  IR absorptive           13310  layer 10  IR absorptive           13311  layer 11  IR absorptive           13312  layer 12  IR absorptive           13313  layer 13  IR absorptive           13314  layer 14  IR absorptive           13315  layer 15  IR absorptive           13317  layer 17  IR absorptive           13318  layer 18  IR absorptive           13319  layer 19  IR absorptive           13320  layer 20______________________________________ 
    
     
                       TABLE 181______________________________________      Photo-      Photo-    Photo-Drum       conductive  conductive                            conductiveNo.        layer 4     layer 5   layer 7______________________________________IR absorptive      13401       13421     13441layer 1IR absorptive      13402       13422     13442layer 2IR absorptive      13403       13423     13443layer 3IR absorptive      13404       13424     13444layer 4IR absorptive      13405       13425     13445layer 5IR absorptive      13406       13426     13446layer 6IR absorptive      13407       13427     13447layer 7IR absorptive      13408       13428     13448layer 8IR absorptive      13409       13429     13449layer 9IR absorptive      13410       13430     13450layer 10IR absorptive      13411       13431     13451layer 11IR absorptive      13412       13432     13452layer 12IR absorptive      13413       13433     13453layer 13IR absorptive      13414       13434     13454layer 14IR absorptive      13415       13435     13455layer 15IR absorptive      13416       13436     13456layer 16IR absorptive      13417       13437     13457layer 17IR absorptive      13418       13438     13458layer 18IR absorptive      13419       13439     13459layer 19IR absorptive      13420       13440     13460layer 20______________________________________ 
    
     
                       TABLE 182______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    13501     13521     13541   13561layer 1IR absorptive    13502     13522     13542   13562layer 2IR absorptive    13503     13523     13543   13563layer 3IR absorptive    13504     13524     13544   13564layer 4IR absorptive    13505     13525     13545   13565layer 5IR absorptive    13506     13526     13546   13566layer 6IR absorptive    13507     13527     13547   13567layer 7IR absorptive    13508     13528     13548   13568layer 8IR absorptive    13509     13529     13549   13569layer 9IR absorptive    13510     13530     13550   13570layer 10IR absorptive    13511     13531     13551   13571layer 11IR absorptive    13512     13532     13552   13572layer 12IR absorptive    13513     13533     13553   13573layer 13IR absorptive    13514     13534     13554   13574layer 14IR absorptive    13515     13535     13555   13575layer 15IR absorptive    13516     13536     13556   13576layer 16IR absorptive    13517     13537     13557   13577layer 17IR absorptive    13518     13538     13558   13578layer 18IR absorptive    13519     13539     13559   13579layer 19IR absorptive    13520     13540     13560   13580layer 20______________________________________ 
    
     
                       TABLE 183______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    13601     13621     13641   13661layer 1IR absorptive    13602     13622     13642   13662layer 2IR absorptive    13603     13623     13643   13663layer 3IR absorptive    13604     13624     13644   13664layer 4IR absorptive    13605     13625     13645   13665layer 5IR absorptive    13606     13626     13646   13666layer 6IR absorptive    13607     13627     13647   13667layer 7IR absorptive    13608     13628     13648   13668layer 8IR absorptive    13609     13629     13649   13669layer 9IR absorptive    13610     13630     13650   13670layer 10IR absorptive    13611     13631     13651   13671layer 11IR absoprtive    13612     13632     13652   13672layer 12IR absorptive    13613     13633     13653   13673layer 13IR absorptive    13614     13634     13654   13674layer 14IR absorptive    13615     13635     13655   13675layer 15IR absorptive    13616     13636     13656   13676layer 16IR absorptive    13617     13637     13657   13677layer 17IR absorptive    13618     13638     13658   13678layer 18IR absorptive    13619     13639     13659   13679layer 19IR absorptive    13620     13640     13660   13680layer 20______________________________________ 
    
     
                                           TABLE 184__________________________________________________________________________Contact  Contact         Contact              Contact                   Contact                        Contact                             ContactLayer 1  Layer 2         Layer 3              Layer 4                   Layer 6                        Layer 7                             Layer 8__________________________________________________________________________Drum    13701    13702         13703              13704                   13705                        13706                             13707No.__________________________________________________________________________ 
    
     
                                           TABLE 185__________________________________________________________________________Charge     Charge          Charge               Charge                    Charge                         Chargeinjection     injection          injection               injection                    injection                         injectionDrum inhibition     inhibition          inhibition               inhibition                    inhibition                         inhibitionNo.  layer 2     layer 3          layer 4               layer 5                    layer 6                         layer 7__________________________________________________________________________Contact13801     13809          13817               13825                    13833                         13841layer 1Contact13802     13810          13818               13826                    13834                         13842layer 2Contact13803     13811          13819               13827                    13835                         13843layer 3Contact13804     13812          13820               13828                    13836                         13844layer 4Contact13805     13813          13821               13829                    13837                         13845layer 5Contact13806     13814          13822               13830                    13838                         13846layer 6Contact13807     13815          13823               13831                    13839                         13847layer 7Contact13808     13816          13824               13832                    13840                         13848layer 8__________________________________________________________________________ 
    
     
                                           TABLE 186__________________________________________________________________________Charge     Charge          Charge               Charge                    Charge                         Charge                              Chargeinjection     injection          injection               injection                    injection                         injection                              injectionDrum inhibition     inhibition          inhibition               inhibition                    inhibition                         inhibition                              inhibitionNo.  layer 1     layer 2          layer 3               layer 4                    layer 5                         layer 6                              layer 7__________________________________________________________________________Contact13901     13909          13917               13925                    13933                         13941                              13949layer 1Contact13902     13910          13918               13926                    13934                         13942                              13950layer 2Contact13903     13911          13919               13927                    13935                         13943                              13951layer 3Contact13904     13912          13920               13928                    13936                         13944                              13952layer 4Contact13905     13913          13921               13929                    13937                         13945                              13953layer 5Contact13906     13914          13922               13930                    13938                         13946                              13954layer 6Contact13907     13915          13923               13931                    13939                         13947                              13955layer 7Contact13908     13916          13924               13932                    13940                         13948                              13956layer 8__________________________________________________________________________ 
    
     
                                           TABLE 187__________________________________________________________________________Charge     Charge          Charge               Charge                    Charge                         Charge                              Chargeinjection     injection          injection               injection                    injection                         injection                              injectionDrum inhibition     inhibition          inhibition               inhibition                    inhibition                         inhibition                              inhibitionNo.  layer 1     layer 2          layer 3               layer 4                    layer 5                         layer 6                              layer 7__________________________________________________________________________Contact14001     14009          14017               14025                    14033                         14041                              14049layer 1Contact14002     14010          14018               14026                    14034                         14042                              14050layer 2Contact14003     14011          14019               14027                    14035                         14043                              14051layer 3Contact14004     14012          14020               14028                    14036                         14044                              14052layer 4Contact14005     14013          14021               14029                    14037                         14045                              14053layer 5Contact14006     14014          14022               14030                    14038                         14046                              14054layer 6Contact14007     14015          14023               14031                    14039                         14047                              14055layer 7Contact14008     14016          14024               14032                    14040                         14048                              14056layer 8__________________________________________________________________________ 
    
     
                       TABLE 188______________________________________Charge injection          Charge injection                       Charge injectioninhibition layer 4          inhibition layer 6                       inhibition 7Drum  14101        14102        14103No.______________________________________ 
    
     
                       TABLE 189______________________________________    Charge    Charge    Charge  Charge    injection injection injection                                injectionDrum     inhibition              inhibition                        inhibition                                inhibitionNo.      layer 1   layer 4   layer 6 layer 7______________________________________Photo-   14201     14203     14205   14207conductivelayer 5Photo-   14202     14204     14206   14208conductivelayer 6______________________________________ 
    
     
                       TABLE 190______________________________________    Charge    Charge    Charge  Charge    injection injection injection                                injectionDrum     inhibition              inhibition                        inhibition                                inhibitionNo.      layer 1   layer 4   layer 6 layer 7______________________________________Photo-   14301     14304     14307   14310conductivelayer 4Photo-   14302     14305     14308   14311conductivelayer 5Photo-   14303     14306     14309   14312conductivelayer 6______________________________________ 
    
     
                       TABLE 191______________________________________    Charge    Charge    Charge  Charge    injection injection injection                                injectionDrum     inhibition              inhibition                        inhibition                                inhibitionNo.      layer 1   layer 4   layer 6 layer 7______________________________________Photo-   14401     14404     14407   14410conductivelayer 4Photo-   14402     14405     14408   14411conductivelayer 5Photo-   14403     14406     14409   14412conductivelayer 6______________________________________ 
    
     
                                           TABLE 192__________________________________________________________________________Gas used and its           Substrate    Inner                             LayerName offlow rate  temperature                  RF power                        pressure                             thicknesslayer(SSCM)     (°C.)                  (W)   (Torr)                             (μm)__________________________________________________________________________SurfaceB.sub.2 H.sub.6 /Ar (20%)        500           250    200   0.35 0.3layerNH.sub.3        100(lowerlayer)SurfaceB.sub.2 H.sub.6 /He (20%)        500           250    100   0.35 0.3layerNH.sub.3        100(upperlayer)__________________________________________________________________________ 
    
     
                       TABLE 193______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    14501     14521     14541   14561layer 1IR absorptive    14502     14522     14542   14562layer 2IR absorptive    14503     14523     14543   14563layer 3IR absorptive    14504     14524     14544   14564layer 4IR absorptive    14505     14525     14545   14565layer 5IR absorptive    14506     14526     14546   14566layer 6IR absorptive    14507     14527     14547   14567layer 7IR absorptive    14508     14528     14548   14568layer 8IR absorptive    14509     14529     14549   14569layer 9IR absorptive    14510     14530     14550   14570layer 10IR absorptive    14511     14531     14551   14571layer 11IR absorptive    14512     14532     14552   14572layer 12IR absorptive    14513     14533     14553   14573layer 13IR absorptive    14514     14534     14554   14574layer 14IR absorptive    14515     14535     14555   14575layer 15IR absorptive    14516     14536     14556   14576layer 16IR absorptive    14517     14537     14557   14577layer 17IR absorptive    14518     14538     14558   14578layer 18IR absorptive    14519     14539     14559   14579layer 19IR absorptive    14520     14540     14560   14580layer 20______________________________________ 
    
     
                       TABLE 194______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    14601     14621     14641   14661layer 1IR absorptive    14602     14622     14642   14662layer 2IR absorptive    14603     14623     14643   14663layer 3IR absortive    14604     14624     14644   14664layer 4IR absorptive    14605     14625     14645   14665layer 5IR absorptive    14606     14626     14646   14666layer 6IR absorptive    14607     14627     14647   14667layer 7IR absorptive    14608     14628     14648   14668layer 8IR absorptive    14609     14629     14649   14669layer 9IR absorptive    14610     14630     14650   14670layer 10IR absorptive    14611     14631     14651   14671layer 11IR absorptive    14612     14632     14652   14672layer 12IR absorptive    14613     14633     14653   14673layer 13IR absorptive    14614     14634     14654   14674layer 14IR absorptive    14615     14635     14655   14675layer 15IR absorptive    14616     14636     14656   14676layer 16IR absorptive    14617     14637     14657   14677layer 17IR absorptive    14618     14638     14658   14678layer 18IR absorptive    14619     14639     14659   14679layer 19IR absorptive    14620     14640     14660   14680layer 20______________________________________ 
    
     
                       TABLE 195______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    14701     14721     14741   14761layer 1IR absorptive    14702     14722     14742   14762layer 2IR absorptive    14703     14723     14743   14763layer 3IR absorptive    14704     14724     14744   14764layer 4IR absorptive    14705     14725     14745   14765layer 5IR absorptive    14706     14726     14746   14766layer 6IR absorptive    14707     14727     14747   14767layer 7IR absorptive    14708     14728     14748   14768layer 8IR absorptive    14709     14729     14749   14769layer 9IR absorptive    14710     14730     14750   14770layer 10IR absorptive    14711     14731     14751   14771layer 11IR absorptive    14712     14732     14752   14772layer 12IR absorptive    14713     14733     14753   14773layer 13IR absorptive    14714     14734     14754   14774layer 14IR absorptive    14715     14735     14755   14775layer 15IR absorptive    14716     14736     14756   14776layer 16IR absorptive    14717     14737     14757   14777layer 17IR absorptive    14718     14738     14758   14778layer 18IR absorptive    14719     14739     14759   14779layer 19IR absorptive    14720     14740     14760   14780layer 20______________________________________ 
    
     
                       TABLE 196______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    14801     14821     14841   14861layer 1IR absorptive    14802     14822     14842   14862layer 2IR absorptive    14803     14823     14843   14863layer 3IR absorptive    14804     14824     14844   14864layer 4IR absorptive    14805     14825     14845   14865layer 5IR absorptive    14806     14826     14846   14866layer 6IR absorptive    14807     14827     14847   14867layer 7IR absorptive    14808     14828     14848   14868layer 8IR absorptive    14809     14829     14849   14869layer 9IR absorptive    14810     14830     14850   14870layer 10IR absorptive    14811     14831     14851   14871layer 11IR absorptive    14812     14832     14852   14872layer 12IR absorptive    14813     14833     14853   14873layer 13IR absorptive    14814     14834     14854   14874layer 14IR absorptive    14815     14835     14855   14875layer 15IR absorptive    14816     14836     14856   14876layer 16IR absorptive    14817     14837     14857   14877layer 17IR absorptive    14818     14838     14858   14878layer 18IR absorptive    14819     14839     14859   14879layer 19IR absorptive    14820     14840     14860   14880layer 20______________________________________ 
    
     
                       TABLE 197______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    14901     14921     14941   14961layer 1IR absorptive    14902     14922     14942   14962layer 2IR absorptive    14903     14923     14943   14963layer 3IR absorptive    14904     14924     14944   14964layer 4IR absorptive    14905     14925     14945   14965layer 5IR absorptive    14906     14926     14946   14966layer 6IR absorptive    14907     14927     14947   14967layer 7IR absorptive    14908     14928     14948   14968layer 8IR absorptive    14909     14929     14949   14969layer 9IR absorptive    14910     14990     14950   14970layer 10IR absorptive    14911     14931     14951   14971layer 11IR absorptive    14912     14932     14952   14972layer 12IR absorptive    14913     14933     14953   14973layer 13IR absorptive    14914     14934     14954   14974layer 14IR absorptive    14915     14935     14955   14975layer 15IR absorptive    14916     14936     14956   14996layer 16IR absorptive    14917     14937     14957   14977layer 17IR absorptive    14918     14938     14958   14978layer 18IR absorptive    14919     14939     14959   14979layer 19IR absorptive    14920     14940     14960   14980layer 20______________________________________ 
    
     
                       TABLE 198______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5 layer 7______________________________________IR absorptive    15051     15021     15041   15061layer 1IR absorptive    15002     15022     15042   15062layer 2IR absorptive    15003     15023     15043   15063layer 3IR absorptive    15004     15024     15044   15064layer 4IR absorptive    15005     15025     15045   15065layer 5IR absorptive    15006     15026     15046   15066layer 6IR absorptive    15007     15027     15047   15067layer 7IR absorptive    15008     15028     15048   15068layer 8IR absorptive    15009     15029     15049   15069layer 9IR absorptive    15010     15030     15050   15070layer 10IR absorptive    15011     15031     15051   15071layer 11IR absorptive    15012     15032     15052   15072layer 12IR absorptive    15013     15033     15053   15073layer 13IR absorptive    15014     15034     15054   15074layer 14IR absorptive    15015     15035     15055   15075layer 15IR absorptive    15016     15036     15056   15076layer 16IR absorptive    15017     15037     15057   15077layer 17IR absorptive    15018     15038     15058   15078layer 18IR absorptive    15019     15039     15059   15079layer 19IR absorptive    15020     15040     15060   15080layer 20______________________________________ 
    
     
                                           TABLE 199__________________________________________________________________________      Gas used and its                    Substrate    Inner                                      Layer      flow rate     temperature                           RF power                                 pressure                                      thicknessDrum No.   (SSCM)        (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________15101    Lower layer      B.sub.2 H.sub.6 /AR (20%)              500   250    200   0.35 0.3      NH.sub.3              100    Upper layer      B.sub.2 H.sub.6 /He (20%)              500   250    100   0.35 0.3      NH.sub.3              10015102    Lower layer      B.sub.2 H.sub.6 /Ar (20%)              500   250    200   0.40 0.3      H.sub.2 100      NH.sub.3              100    Upper layer      B.sub.2 H.sub.6 /He (20%)              500   250    100   0.40 0.3      H.sub.2 100      NH.sub.3              30015103    Lower layer      B.sub.2 H.sub.6 /Ar (20%)              500   250    200   0.35 0.3      NH.sub.3              100      Bias voltage of              -150                  V      the cylinder    Upper layer      B.sub.2 H.sub.6 /He (20%)              500   250    100   0.35 0.3      NH.sub.3              100      Bias voltage of              +100                  V      the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 200__________________________________________________________________________      Gas used and its                    Substrate    Inner                                      Layer      flow rate     temperature                           RF power                                 pressure                                      thicknessDrum No.   (SCCM)        (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________15201    Lower layer      B.sub.2 H.sub.6 /Ar (20%)              500   250    200   0.35 0.3      NH.sub.3              100    Upper layer      B.sub.2 H.sub.6 /He (20%)              500   250    100   0.35 0.3      NH.sub.3              10015202    Lower layer      B.sub.2 H.sub.6 /Ar (20%)              500   250    200   0.40 0.3      H.sub.2 100      NH.sub.3              100    Upper layer      B.sub.2 H.sub.6 /He (20%)              500   250    100   0.40 0.3      H.sub.2 100      NH.sub.3              30015203    Lower layer      B.sub.2 H.sub.6 /Ar (20%)              500   250    200   0.35 0.3      NH.sub.3              100      Bias voltage of              -150                  V      the cylinder    Upper layer      B.sub.2 H.sub.6 /He (20%)              500   250    100   0.35 0.3      NH.sub.3              100      Bias voltage of              +100                  V      the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 201__________________________________________________________________________      Gas used and its                    Substrate    Inner                                      Layer      flow rate     temperature                           RF power                                 pressure                                      thicknessDrum No.   (SCCM)        (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________15301    Lower layer      B.sub.2 H.sub.6 /Ar (20%)              500   250    200   0.35 0.3      NH.sub.3              100    Upper layer      B.sub.2 H.sub.6 /He (20%)              500   250    100   0.35 0.3      NH.sub.3              10015302    Lower layer      B.sub.2 H.sub.6 /Ar (20%)              500      H.sub.2 100   250    200   0.40 0.3      NH.sub.3              100    Upper layer      B.sub.2 H.sub.6 /He (20%)              500   250    100   0.40 0.3      H.sub.2 100      NH.sub.3              30015303    Lower layer      B.sub.2 H.sub.6 /Ar (20%)              500   250    200   0.35 0.3      NH.sub.3              100      Bias voltage of              -150                  V      the cylinder    Upper layer      B.sub.2 H.sub.6 /He (20%)              500   250    100   0.35 0.3      NH.sub.3              100      Bias voltage of              +100                  V      the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 202__________________________________________________________________________ Gas used and its                 Substrate    Inner                                   LayerName of flow rate       temperature                        RF power                              pressure                                   thicknesslayer (SCCM)          (°C.)                        (W)   (Torr)                                   (μm)__________________________________________________________________________Charge SiH.sub.4 100   250    150   0.35 3injection H.sub.2   100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)           1000              ppmlayer NO        10Photo- SiH.sub.4 200   250    300   0.40 20conductive H.sub.2   200layerInter- SiH.sub.4 10    250    150   0.35 0.3mediate CH.sub.4  400layerSurface B.sub.2 H.sub.6 /Ar (20%)           500   250    200   0.35 0.3layer NH.sub.3  100(lowerlayer)Surface B.sub.2 H.sub.6 /He (20%)           500   250    100   0.35 0.3layer NH.sub.3  100(upperlayer)__________________________________________________________________________ 
    
     
                                           TABLE 203 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)               100                  ppmlayer NO            4Surface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 203 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)               100                  ppmlayer NO            4Surface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 204______________________________________  IntialDrum   electrification             Residual       Defective                                    ImageNo.    efficiency voltage  Ghost image   flow______________________________________(a)    ○   ⊚                      ⊚                            ⊚                                    ○(b)    ○   ⊚                      ⊚                            ⊚                                    ○______________________________________Drum   Increase of Surface   Breakdown                                 AbrasionNo.    defective image              abrasion  voltage  resistance______________________________________(a)    ○    ⊚                        ⊚                                 ⊚(b)    ○    ⊚                        ⊚                                 ⊚______________________________________ ⊚ : Excellent  ○  : Good 
    
     
                                           TABLE 205 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)               100                  ppmlayer NO            4Surface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.40 0.5layer H.sub.2       100 NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               50 ppm__________________________________________________________________________ 
    
     
                                           TABLE 205 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)               100                  ppmlayer NO            4Surface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.40 0.5layer H.sub.2       100 NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               50 ppm__________________________________________________________________________ 
    
     
                       TABLE 206______________________________________  Initial  electri-Drum   fication Residual        Defective                                   ImageNo.    efficiency           voltage  Ghost  image   flow______________________________________(a)     ○           ⊚                    ⊚                           ⊚                                    ○(b)     ○           ⊚                    ⊚                           ⊚                                    ○______________________________________    Increase    of                   BreakDrum     defective             Surface     down  AbrasionNo.      image    abrasion    voltage                               resistance______________________________________(a)       ○             ⊚                         ⊚                               ⊚(b)       ○             ⊚                         ⊚                               ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                       TABLE 207______________________________________  Initial  electri-Drum   fication Residual        Defective                                   ImageNo.    efficiency           voltage  Ghost  image   flow______________________________________(a)     ○           ⊚                    ⊚                           ⊚                                    ○(b)     ○           ⊚                    ⊚                           ⊚                                    ○______________________________________    Increase    of                   BreakDrum     defective             Surface     down  AbrasionNo.      image    abrasion    voltage                               resistance______________________________________(a)       ○             ⊚                         ⊚                               ⊚(b)       ○             ⊚                         ⊚                               ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 208 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Charge SiH.sub.4     100   250    150   0.35  3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 208 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Charge SiH.sub.4     100   250    150   0.35  3injection H.sub.2       100inhibition PH.sub.3 (against SiH.sub.4)               800                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 209______________________________________  Initial  electri-Drum   fication Residual        Defective                                   ImageNo.    efficiency           voltage  Ghost  image   flow______________________________________(a)    ⊚           ⊚                    ⊚                           ⊚                                    ○(b)    ⊚           ⊚                    ⊚                           ⊚                                    ○______________________________________    Increase    of                   BreakDrum     defective             Surface     down  AbrasionNo.      image    abrasion    voltage                               resistance______________________________________(a)       ○             ⊚                         ⊚                               ⊚(b)       ○             ⊚                         ⊚                               ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 210 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Photo- SiH.sub.4     200  250     300   0.40                                      20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500  250     200   0.35                                      0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 210 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Photo- SiH.sub.4     200  250     300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500  250     200   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 211______________________________________  Initial  electri-Drum   fication Residual        Defective                                   ImageNo.    efficiency           voltage  Ghost  image   flow______________________________________(a)    ⊚           ⊚                    ⊚                           ⊚                                    ○(b)    ⊚           ⊚                    ⊚                           ⊚                                    ○______________________________________    Increase    of                   BreakDrum     defective             Surface     down  AbrasionNo.      image    abrasion    voltage                               resistance______________________________________(a)       ○             ⊚                         ⊚                               ⊚(b)       ○             ⊚                         ⊚                               ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 212 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________IR    SiH.sub.4     100   250    150   0.35  1absorptive H.sub.2       100layer GeH.sub.4     50 B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppm NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 212 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________IR    SiH.sub.4     100  250     150   0.35  1absorptive H.sub.2       100layer GeH.sub.4     50 PH.sub.3 (against SiH.sub.4)               800                  ppm NO            10Photo- SiH.sub.4     200  250     300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500  250     200   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 213______________________________________  Initial  electri-Drum   fication Residual        Defective                                   ImageNo.    efficiency           voltage  Ghost  image   flow______________________________________(a)     ○           ⊚                    ⊚                           ⊚                                    ○(b)     ○           ⊚                    ⊚                           ⊚                                    ○______________________________________ Increase of                BreakDrum  defective          Surface  down   Abrasion                                 InterferenceNo.   image    abrasion voltage                          resistance                                 fringe______________________________________(a)    ○          ⊚                   ⊚                          ⊚                                  ○(b)    ○          ⊚                   ⊚                          ⊚                                  ○______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 214 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4      20   250    100   0.25 0.5layer N.sub.2       100Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 214 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4      20   250    100   0.25 0.5layer N.sub.2       100Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 215______________________________________ InitialDrum  electrification            Residual        Defective                                    ImageNo.   efficiency voltage  Ghost  image   flow______________________________________(a)   ⊚            ⊚                     ⊚                            ⊚                                    ○(b)   ⊚            ⊚                     ⊚                            ⊚                                    ○______________________________________   Increase of          BreakDrum    defective Surface    down   AbrasionNo.     image     abrasion   voltage                               resistance______________________________________(a)     ○  ⊚                        ⊚                               ⊚(b)     ○  ⊚                        ⊚                               ⊚______________________________________ ⊚: Exellent  ○ : Good 
    
     
                                           TABLE 216 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________IR    SiH.sub.4     100   250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4     50 B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppm NO            10Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 216 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________IR    SiH.sub.4     100   250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4     50 PH.sub.3 (against SiH.sub.4)               800                  ppm NO            10Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition PH.sub.3 (against SiH.sub.4)               800                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 217______________________________________ InitialDrum  electrification            Residual        Defective                                    ImageNo.   efficiency voltage  Ghost  image   flow______________________________________(a)   ⊚            ⊚                     ⊚                            ⊚                                    ○(b)   ⊚            ⊚                     ⊚                            ⊚                                    ○______________________________________ Increase of        BreakDrum  defective Surface  down  Abrasion                                 InterferenceNo.   image     abrasion voltage                          resistence                                 fringe______________________________________(a)   ○  ⊚                    ⊚                          ⊚                                 ○(b)   ○  ⊚                    ⊚                          ⊚                                 ○______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 218 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4     20    250     50   0.05 0.5layer N.sub.2       10Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 218 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4     20    250     50   0.05 0.5layer N.sub.2       10Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition PH.sub.3 (against SiH.sub.4)               800                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 219______________________________________ InitialDrum  electrification            Residual        Defective                                    ImageNo.   efficiency voltage  Ghost  image   flow______________________________________(a)   ⊚            ⊚                     ⊚                            ⊚                                    ⊚(b)   ⊚            ⊚                     ⊚                            ⊚                                    ⊚______________________________________   Increase of          BreakDrum    defective Surface    down   AbrasionNo.     image     abrasion   voltage                               resistance______________________________________(a)     ○  ○   ⊚                               ⊚(b)     ○  ○   ⊚                               ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 220 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperatrue                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4     20    250     50   0.05 0.5layer N.sub.2       10IR    SiH.sub.4     100   250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4     50 B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppm NO            10Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 220 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4     20    250     50   0.05 0.5layer N.sub.2       10IR    SiH.sub.4     100   250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4     50 PH.sub.3 (against SiH.sub.4)               800                  ppm NO            10Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition PH.sub.3 (against SiH.sub.4)               800                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 221______________________________________ InitialDrum  electrification            Residual        Defective                                    ImageNo.   efficiency voltage  Ghost  image   flow______________________________________(a)   ⊚            ⊚                     ⊚                            ⊚                                    ○(b)   ⊚            ⊚                     ⊚                            ⊚                                    ○______________________________________ Increase of        BreakDrum  defective Surface  down  Abrasion                                 InterferenceNo.   image     abrasion voltage                          resistance                                 fringe______________________________________(a)   ○  ⊚                    ⊚                          ⊚                                 ○(b)   ○  ⊚                    ⊚                          ⊚                                 ○______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 222__________________________________________________________________________    Gas used and its               Substrate    Inner                                 LayerDrum    flow rate       temperature                      RF power                            pressure                                 thicknessNo. (SCCM)          (°C.)                      (W)   (Torr)                                 (μm)__________________________________________________________________________16701    SiH.sub.4 200   250    300   0.40 20    He        200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        416702    SiF.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        616703    SiH.sub.4 200   250    300   0.40 20    H.sub.2   20016704    SiH.sub.4 200   250    250   0.40 20    Ar        20016705    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   20016706*    SiH.sub.4 200   250    300   0.40 20    He        200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        416707*    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        616708*    SiH.sub.4 200   250    300   0.40 20    H.sub.2   20016709*    SiH.sub.4 200   250    250   0.40 20    Ar        20016710*    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200__________________________________________________________________________ *surface layer followed Table 203 (b) markless case: followed Table 203 (a) 
    
     
                                           TABLE 223__________________________________________________________________________    Gas used and its               Substrate    Inner                                 LayerDrum    flow rate       temperature                      RF power                            pressure                                 thicknessNo. (SCCM)          (°C.)                      (W)   (Torr)                                 (μm)__________________________________________________________________________16801    SiH.sub.4 200   250    300   0.40 20    He        200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        416802    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        616803    SiH.sub.4 200   250    300   0.40 20    H.sub.2   20016804    SiH.sub.4 200   250    250   0.40 20    Ar        20016805    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   20016806*    SiH.sub.4 200   250    300   0.40 20    He        200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        416807*    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        616808*    SiH.sub.4 200   250    300   0.40 20    H.sub.2   20016809*    SiH.sub.4 200   250    250   0.40 20    Ar        20016810*    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200__________________________________________________________________________ *surface layer followed Table 205 (b) markless case: followed Table 205 (a) 
    
     
                                           TABLE 224__________________________________________________________________________    Gas used and its               Substrate    Inner                                 LayerDrum    flow rate       temperature                      RF power                            pressure                                 thicknessNo. (SCCM)          (°C.)                      (W)   (Torr)                                 (μm)__________________________________________________________________________16901    SiH.sub.4 200   250    300   0.40 20    He        200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        416902    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        616903    SiH.sub.4 200   250    300   0.40 20    H.sub.2   20016304    SiH.sub.4 200   250    250   0.40 20    Ar        20016905    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   20016906*    SiH.sub.4 200   250    300   0.40 20    He        200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        416907*    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200    B.sub.2 H.sub.6 (against SiH.sub. 4)         100            ppm    NO        616908*    SiH.sub.4 200   250    300   0.40 20    H.sub.2   20016309*    SiH.sub.4 200   250    250   0.40 20    Ar        20016910*    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200__________________________________________________________________________ *surface layer followed Table 203 (b) markless case: followed Table 203 (a) 
    
     
                                           TABLE 225__________________________________________________________________________    Gas used and its               Substrate    Inner                                 LayerDrum    flow rate       temperature                      RF power                            pressure                                 thicknessNo. (SCCM)          (°C.)                      (W)   (Torr)                                 (μm)__________________________________________________________________________17001    SiH.sub.4 100   250    150   0.35 3    H.sub.2   100    B.sub.2 H.sub.6 (against SiH.sub.4)         1000            ppm    GeH.sub.4 10    NO        1017002    SiH.sub.4 80    250    170   0.25 3    SiF.sub.4 20    B.sub.2 H.sub.6 (against SiH.sub.4)         1000            ppm    SnH.sub.4 5    NO        517003    SiH.sub.4 100   250    130   0.25 3    B.sub.2 H.sub.6 (against SiH.sub.4)         800            ppm    NO        4    N.sub.2   4    CH.sub.4  617004*    SiH.sub.4 100   250    150   0.35 3    H.sub.2   100    PH.sub.3 (against SiH.sub.4)         800            ppm17005*    SiH.sub.4 100   250    130   0.25 3    PH.sub.3 (against SiH.sub.4)         800            ppm    GeH.sub.4 10    NO        1017006    SiH.sub.4 100   250    150   0.35 3    H.sub.2   100    B.sub.2 H.sub.6 (against SiH.sub.4)         1000            ppm    NO**      10NO***         10 → 0****__________________________________________________________________________ *surface layer followed Table 208(b) markless case: followed Table 208(a) **Substrate side 2 μm ***Surface layer side 1 μm ****Constantly changed 
    
     
                                           TABLE 226__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5*                          layer 6*                               layer 7__________________________________________________________________________Photo- 17101      17106           17111                17116                     17121                          17126                               17131conductivelayer 1Photo- 17102      17107           17112                17117                     17122                          17127                               17132conductivelayer 2Photo- 17103      17108           17113                17118                     17123                          17128                               17133conductivelayer 3Photo- 17104      17109           17114                17119                     17124                          17129                               17134conductivelayer 5Photo- 17105      17110           17115                17120                     17125                          17130                               17135conductivelayer 6__________________________________________________________________________ *surface layer followed Table 6 (b) markless case: followed Table 6 (a) 
    
     
                                           TABLE 227__________________________________________________________________________Gas used and its    Substrate    Inner                                      LayerName offlow rate           temperature                           RF power                                 pressure                                      thicknesslayer(SCCM)              (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________Surface*B.sub.2 H.sub.6 /Ar (20%)              500   250    200   0.40 0.5layer AH.sub.2       100NH.sub.3      100SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)              50 ppmSurface*B.sub.2 H.sub.6 /Ar (20%)              500   250    200   0.40 0.5layer BH.sub.2       100NH.sub.3      100GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)              50 ppm__________________________________________________________________________ *each of the surface layers A and B is individually used in accordance with the kind of the lower layer 
    
     
                                           TABLE 228__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5*                          layer 6*                               layer 7__________________________________________________________________________Photo- 17201      17207           17213                17219                     17225                          17231                               17237conductivelayer 1Photo- 17202      17208           17214                17220                     17226                          17232                               17238conductivelayer 2Photo- 17203      17209           17215                17221                     17227                          17233                               17239conductivelayer 3Photo- 17204      17210           17216                17222                     17228                          17234                               17240conductivelayer 4Photo- 17205      17211           17217                17223                     17229                          17235                               17241conductivelayer 5Photo- 17206      17212           17218                17224                     17230                          17236                               17242conductivelayer 6__________________________________________________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 229__________________________________________________________________________Gas used and its     Substrate    Inner                                       LayerName offlow rate            temperature                            RF power                                  pressure                                       thicknesslayer(SCCM)               (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Surface*B.sub.2 H.sub.6 /Ar (20%)              500    250    200   0.35 0.5layer ANH.sub.3      100SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)              100 ppmBias voltage of              -150                  Vthe cylinderSurface*B.sub.2 H.sub.6 /Ar (20%)              500    250    200   0.35 0.5layer BNH.sub.3      100GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)              100 ppmBias voltage of              -150                  Vthe cylinder__________________________________________________________________________ *each of the surface layers A and B is individually used in accordance with the kind of the lower layer 
    
     
                                           TABLE 230__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5*                          layer 6*                               layer 7__________________________________________________________________________Photo- 17301      17307           17313                17319                     17325                          17331                               17337conductivelayer 1Photo- 17302      17308           17314                17320                     17326                          17362                               17338conductivelayer 2Photo- 17303      17309           17315                17321                     17327                          17333                               17339conductivelayer 3Photo- 17304      17310           17316                17322                     17328                          17334                               17340conductivelayer 4Photo- 17305      17311           17317                17323                     17329                          17335                               17341conductivelayer 5Photo- 17306      17312           17318                17324                     17330                          17336                               17342conductivelayer 6__________________________________________________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 231______________________________________Photo-               Photo-           Photo-con-       Photo-    con-     Photo-  con-ductive    conductive                ductive  conductive                                 ductiveLayer 1    Layer 2   Layer 3  Layer 5 Layer 6______________________________________Drum  17401    17402     17403  17404   17405No.   17406*   17407*    17408* 17409*  17410*______________________________________ *Surface layer followed Table 210 (b) Markless case: followed Table 210 (a) 
    
     
                       TABLE 232______________________________________Photo-     Photo-  Photo-   Photo-                             Photo- Photo-con-       con-    con-     con-  con-   con-ductive    ductive ductive  ductive                             ductive                                    ductivelayer 1    layer 2 layer 3  layer 4                             layer 5                                    layer 6______________________________________Drum  17501    17502   17503  17504 17505  17506No.   17507*   17508*  17509* 17510*                               17511* 17512*______________________________________ *surface layer B was used. markless case: surface layer A was used. 
    
     
                       TABLE 233______________________________________Photo-     Photo-  Photo-   Photo-                             Photo- Photo-con-       con-    con-     con-  con-   con-ductive    ductive ductive  ductive                             ductive                                    ductivelayer 1    layer 2 layer 3  layer 4                             layer 5                                    layer 6______________________________________Drum  17601    17602   17603  17604 17605  17606No.   17607*   17608*  17609* 17610*                               17611* 17612*______________________________________ *surface layer B was used. *markless case: surface layer A was used. 
    
     
                       TABLE 234______________________________________          Drum          No.______________________________________IR Absorptive    17701   17720*Layer 1IR Absorptive    17702   17721*Layer 2IR Absorptive    17703   17722*Layer 3IR Absorptive    17704   17723*Layer 4IR Absorptive    17705   17724*Layer 5IR Absorptive    17706   --Layer 6IR Absorptive    17707   --Layer 7IR Absorptive    17708   --Layer 8IR Absorptive    17709   --Layer 9IR Absorptive    17710   --Layer 10IR Absorptive    17711   --Layer 11IR Absorptive    17712   --Layer 12IR Absorptive    17713   --Layer 13IR Absorptive    17714   --Layer 14IR Absorptive    17715   --Layer 15IR Absorptive    17716   --Layer 17IR Absorptive    17717   17725*Layer 18IR Absorptive    17718   17726*Layer 19IR Absorptive    17719   17727*Layer 20______________________________________ *:Surface layer followed Table 212(b) Markless case:followed 212(a) 
    
     
                                           TABLE 235__________________________________________________________________________  Photo- Photo-               Photo- Photo-                            Photo-Drum   conductive         conductive               conductive                      conductive                            conductiveNo.    layer 1         layer 2               layer 3                      layer 5                            layer 6__________________________________________________________________________IR absorptive  17801  17821 17841  17861 17881layer 1IR absorptive  17802  17822 17842  17862 17882layer 2IR absorptive  17803  17823 17843  17863 17883layer 3IR absorptive  17804  17824 17844  17864 17884layer 4IR absorptive  17805  17825 17845  17865 17885layer 5IR absorptive  17806  17826 17846  17866 17886layer 6IR absorptive  17807  17827 17847  17867 17887layer 7IR absorptive  17808  17828 17848  17868 17888layer 8IR absorptive  17809  17829 17849  17869 17889layer 9IR absorptive  17810  17830 17850  17870 17890layer 10IR absorptive  17811  17831 17851  17871 17891layer 11*IR absorptive  17812  17832 17852  17872 17892layer 12*IR absorptive  17813  17833 17853  17873 17893layer 13*IR absorptive  17814  17834 17854  17874 17894layer 14*IR absorptive  17815  17835 17855  17875 17895layer 15*IR absorptive  17816  17836 17856  17876 17896layer 16IR absorptive  17817  17837 17857  17877 17897layer 17*IR absorptive  17818  17838 17858  17878 17898layer 18IR absorptive  17819  17839 17859  17879 17899layer 19IR absorptive  17820  17840 17860  17880 178100layer 20__________________________________________________________________________ *: surface layer followed Table 212(b) markless case: followed Table 212(a) 
    
     
                                           TABLE 236__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-                                Photo-Drum   conductive        conductive              conductive                    conductive                          conductive                                conductiveNo.    layer 1        layer 2              layer 3                    layer 4                          layer 5                                layer 6__________________________________________________________________________IR absorptive  17901 17921 17941 17961 17981 179101layer 1IR absorptive  17902 17922 17942 17962 17982 179102layer 2IR absorptive  17903 17923 17943 17963 17983 179103layer 3IR absorptive  17904 17924 17944 17964 17984 179104layer 4IR absorptive  17905 17925 17945 17965 17985 179105layer 5IR absorptive  17906 17926 17946 17966 17986 179106layer 6IR absorptive  17907 17927 17947 17967 17987 179107layer 7IR absorptive  17908 17928 17948 17968 17988 179108layer 8IR absorptive  17909 17929 17949 17969 17989 179109layer 9IR absorptive  17910 17930 17950 17970 17990 179110layer 10IR absorptive  17911 17931 17951 17971 17991 179111layer 11*IR absorptive  17912 17932 17952 17972 17992 179112layer 12*IR absorptive  17913 17933 17953 17973 17993 179113layer 13*IR absorptive  17914 17934 17954 17974 17994 179114layer 14*IR absorptive  17915 17935 17955 17975 17995 179115layer 15*IR absorptive  17916 17936 17956 17976 17996 179116layer 16IR absorptive  17917 17937 17957 17977 17997 179117layer 17*IR absorptive  17918 17938 17958 17978 17998 179118layer 18IR absorptive  17919 17939 17959 17979 17999 179119layer 19IR absorptive  17920 17940 17960 17980 179100                                179120layer 20__________________________________________________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 237__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-                                Photo-Drum   conductive        conductive              conductive                    conductive                          conductive                                conductiveNo.    layer 1        layer 2              layer 3                    layer 4                          layer 5                                layer 6__________________________________________________________________________IR absorptive  18001 18021 18041 18061 18081 180101layer 1IR absorptive  18002 18022 18042 18062 18082 180102layer 2IR absorptive  18003 18023 18043 18063 18083 180103layer 3IR absorptive  18004 18024 18044 18064 18084 180104layer 4IR absorptive  18005 18025 18045 18065 18085 180105layer 5IR absorptive  18006 18026 18046 18066 18086 180106layer 6IR absorptive  18007 18027 18047 18067 18087 180107layer 7IR absorptive  18008 18028 18048 18068 18088 180108layer 8IR absorptive  18009 18029 18049 18069 18089 180109layer 9IR absorptive  18010 18030 18050 18070 18090 180110layer 10IR absorptive  18011 18031 18051 18071 18091 180111layer 11*IR absorptive  18012 18032 18052 18072 18092 180112layer 12*IR absorptive  18013 18033 18053 18073 18093 180113layer 13*IR absorptive  18014 18034 18054 18074 18094 180114layer 14*IR absorptive  18015 18035 18055 18075 18095 180115layer 15*IR absorptive  18016 18036 18056 18076 18096 180116layer 16IR absorptive  18017 18037 18057 18077 18097 180117layer 17*IR absorptive  18018 18038 18058 18078 18098 180118layer 18IR absorptive  18019 18039 18059 18079 18099 180119layer 19IR absorptive  18020 18040 18060 18080 180100                                180120layer 20__________________________________________________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 238______________________________________Contact           Contact  ContactLayer 2           Layer 3  Layer 4______________________________________Drum    18101         18102    18103No.     18104*        18105*   18106*______________________________________ *Surface layer followed Table 214 (b) Markless case: followed Table 214 (a) 
    
     
                       TABLE 239______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-   18201      18207*   18213   18219conductivelayer 1Photo-   18202     18208      18214* 18220conductivelayer 2Photo-    18203*   18209     18215   18221conductivelayer 3Photo-   18204     18210     18216    18222*conductivelayer 4Photo-   18205     18211      18217* 18223conductivelayer 5Photo-   18206      18212*   18218   18224conductivelayer 6______________________________________ *surface layer followed Table 214 (b) markless case: followed Table 214 (a) 
    
     
                       TABLE 240______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-   18301     18307      18313* 18319conductivelayer 1Photo-   18302      18308*   18314   18320conductivelayer 2Photo-   18303     18309     18315    18321*conductivelayer 3Photo-    18304*   18310     18316   18322conductivelayer 4Photo-   18305      18311*   18317   18323conductivelayer 5Photo-   18306     18312      18318* 18324conductivelayer 6______________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 241______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-    18402*   18407     18413   18419conductivelayer 1Photo-   18402     18408      18414* 18420conductivelayer 2Photo-   18403     18409     18415    18421*conductivelayer 3Photo-   18404      18410*   18416   18422conductivelayer 4Photo-   18405     18411     18417    18423*conductivelayer 5Photo-    18406*   18412     18418   18424conductivelayer 6______________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 242______________________________________          Drum          No.______________________________________IR absorptive    18501   18521layer 1                  *IR absorptive    18502   18522layer 2                  *IR absorptive    18503   18523layer 3                  *IR absorptive    18504   18524layer 4                  *IR absorptive    18505   18526layer 5                  *IR absorptive    18506   18526layer 6                  *IR absorptive    18507   18527layer 7                  *IR absorptive    18508   18528layer 8                  *IR absorptive    18509   18529layer 9                  *IR absorptive    18510   18530layer 10                 *IR absorptive    18511   18531layer 11                 *IR absorptive    18512   18532layer 12                 *IR absorptive    18513   18533layer 13                 *IR absorptive    18514   18534layer 14                 *IR absorptive    18515   18535layer 15                 *IR absorptive    18516   18536layer 16                 *IR absorptive    18517   18537layer 17                 *IR absorptive    18518   18538layer 18                 *IR absorptive    18519   18539layer 19                 *IR absorptive    18520   18540layer 20                 *______________________________________  *Charge injection inhibition layer and surface layer followed Table 216(b) markless case: followed Table 216(a) 
    
     
                       TABLE 243______________________________________      Photo-      Photo-    Photo-Drum       conductive  conductive                            conductiveNo.        layer 4     layer 5*  layer 7______________________________________IR absorptive      18601       18621     18641layer 1IR absorptive      18602       18622     18642layer 2IR absorptive      18603       18623     18643layer 3IR absorptive      18604       18624     18644layer 4IR absorptive      18605       18625     18645layer 5IR absorptive      18606       18626     18646layer 6IR absorptive      18607       18627     18647layer 7IR absorptive      18608       18628     18648layer 8IR absorptive      18609       18629     18649layer 9IR absorptive      18610       18630     18650layer 10IR absorptive      18611       18631     18651layer 11IR absorptive      18612       18632     18652layer 12IR absorptive      18613       18633     18653layer 13IR absorptive      18614       18634     18654layer 14IR absorptive      18615       18635     18655layer 15IR absorptive      18616       18636     18656layer 16IR absorptive      18617       18637     18657layer 17IR absorptive      18618       18638     18658layer 18IR absorptive      18619       18639     18659layer 19IR absorptive      18620       18640     18660layer 20______________________________________  *surface layer followed Table 216(b) markless case: followed Table 216(a) 
    
     
                       TABLE 244______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    18701     18721     18741   18761layer 1IR absorptive    18702     18722     18742   18762layer 2IR absorptive    18703     18723     18743   18763layer 3IR absorptive    18704     18724     18744   18764layer 4IR absorptive    18705     18725     18745   18765layer 5IR absorptive    18706     18726     18746   18766layer 6IR absorptive    18707     18727     18747   18767layer 7IR absorptive    18708     18728     18748   18768layer 8IR absorptive    18709     18729     18749   18769layer 9IR absorptive    18710     18730     18750   18770layer 10IR absorptive    18711     18731     18751   18771layer 11IR absorptive    18712     18732     18752   18772layer 12IR absorptive    18713     18733     18753   18773layer 13IR absorptive    18714     18734     18754   18774layer 14IR absorptive    18715     18735     18755   18775layer 15IR absorptive    18716     18736     18756   18776layer 16IR absorptive    18717     18737     18757   18777layer 17IR absorptive    18718     18738     18758   18778layer 18IR absorptive    18719     18739     18759   18779layer 19IR absorptive    18720     18740     18760   18780layer 20______________________________________  *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 245______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    18801     18821     18841   18861layer 1IR absorptive    18802     18822     18842   18862layer 2IR absorptive    18803     18823     18843   18863layer 3IR absorptive    18804     18824     18844   18864layer 4IR absorptive    18805     18825     18845   18865layer 5IR absorptive    18806     18826     18846   18866layer 6IR absorptive    18807     18827     18847   18867layer 7IR absorptive    18808     18828     18848   18868layer 8IR absorptive    18809     18829     18849   18869layer 9IR absorptive    18810     18830     18850   18870layer 10IR absorptive    18811     18831     18851   18871layer 11IR absorptive    18812     18832     18852   18872layer 12IR absorptive    18813     18833     18853   18873layer 13IR absorptive    18814     18834     18854   18874layer 14IR absorptive    18815     18835     18855   18875layer 15IR absorptive    18816     18836     18856   18876layer 16IR absorptive    18817     18837     18857   18877layer 17IR absorptive    18818     18838     18858   18878layer 18IR absorptive    18819     18839     18859   18879layer 19IR absorptive    18820     18840     18860   18880layer 20______________________________________  *surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 246__________________________________________________________________________Contact  Contact         Contact              Contact                   Contact                        Contact                             ContactLayer 1  Layer 2         Layer 3              Layer 4                   Layer 6                        Layer 7                             Layer 8__________________________________________________________________________Drum    18901    18902         18903              18904                   18905                        18906                             18907No. 18908*    18909*         18910*              18911*                   18912*                        18913*                             18914*__________________________________________________________________________ *Charge injection inhibition layer and surface layer followed Table 218 (b) Markless case: followed Table 218 (a) 
    
     
                                           TABLE 247__________________________________________________________________________ Charge      Charge            Charge                 Charge                       Charge                            Charge injection      injection            injection                 injection                       injection                            injectionDrum  inhibition      inhibition            inhibition                 inhibition                       inhibition                            inhibitionNo.   layer 2      layer 3            layer 4                 layer 5*                       layer 6*                            layer 7__________________________________________________________________________Contact 19001      19009 19017                 19025 19033                            19041layer 1Contact 19002      19010 19018                 19026 19034                            19042layer 2Contact 19003      19011 19019                 19027 19035                            19043layer 3Contact 19004      19012 19020                 19028 19036                            19044layer 4Contact 19005      19013 19021                 19029 19037                            19045layer 5Contact 19006      19014 19022                 19030 19038                            19046layer 6Contact 19007      19015 19023                 19031 19039                            19047layer 7Contact 19008      19016 19024                 19032 19040                            19048layer 8__________________________________________________________________________ *surface layer followed Table 218 (b) markless case: followed Table 218 (a) 
    
     
                                           TABLE 248__________________________________________________________________________Charge     Charge          Charge               Charge                    Charge                         Charge                              Chargeinjection     injection          injection               injection                    injection                         injection                              injectionDrum inhibition     inhibition          inhibition               inhibition                    inhibition                         inhibition                              inhibitionNo.  layer 1     layer 2          layer 3               layer 4                    layer 5*                         layer 6*                              layer 7__________________________________________________________________________Contact19101     19109          19117               19125                    19133                         19141                              19149layer 1Contact19102     19110          19118               19126                    19134                         19142                              19150layer 2Contact19103     19111          19119               19127                    19135                         19143                              19151layer 3Contact19104     19112          19120               19128                    19136                         19144                              19152layer 4Contact19105     19113          19121               19129                    19137                         19145                              19153layer 5Contact19106     19114          19122               19130                    19138                         19146                              19154layer 6Contact19107     19115          19123               19131                    19139                         19147                              19155layer 7Contact19108     19116          19124               19132                    19140                         19148                              19156layer 8__________________________________________________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 249__________________________________________________________________________Charge     Charge          Charge               Charge                    Charge                         Charge                              Chargeinjection     injection          injection               injection                    injection                         injection                              injectionDrum inhibition     inhibition          inhibition               inhibition                    inhibition                         inhibition                              inhibitionNo.  layer 1     layer 2          layer 3               layer 4                    layer 5*                         layer 6*                              layer 7__________________________________________________________________________Contact19201     19209          19217               19225                    19233                         19241                              19249layer 1Contact19202     19210          19218               19226                    19234                         19242                              19250layer 2Contact19203     19211          19219               19227                    19235                         19243                              19251layer 3Contact19204     19212          19220               19228                    19236                         19244                              19252layer 4Contact19205     19213          19221               19229                    19237                         19245                              19253layer 5Contact19206     19214          19222               19230                    19238                         19246                              19254layer 6Contact19207     19215          19223               19231                    19239                         19247                              19255layer 7Contact19208     19216          19224               19232                    19240                         19248                              19256layer 8__________________________________________________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 250______________________________________Charge            Charge   Chargeinjection         injection                      injectioninhibition        inhibition                      inhibitionlayer 4           layer 6* layer 7______________________________________Drum    19301         19302    19303No.______________________________________ *surface layer followed Table 220 (b) markless case: followed Table 220 (a) 
    
     
                       TABLE 251______________________________________    Charge   Charge     Charge Charge    injection             injection  injection                               injectionDrum     inhibition             inhibition inhibition                               inhibitionNo.      layer 1  layer 4    layer 6*                               layer 7______________________________________Photo-   19401    19403      19405  19407conductivelayer 5Photo-   19402    19404      19406  19408conductivelayer 6______________________________________ *surface layer followed Table 220 (b) markless case: followed Table 220 (a) 
    
     
                       TABLE 252______________________________________    Charge   Charge     Charge Charge    injection             injection  injection                               injectionDrum     inhibition             inhibition inhibition                               inhibitionNo.      layer 1  layer 4    layer 6*                               layer 7______________________________________Photo-   19501    19504      19507  19510conductivelayer 4Photo-   19502    19505      19508  19511conductivelayer 5Photo-   19503    19506      19509  19512conductivelayer 6______________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 253______________________________________    Charge   Charge     Charge Charge    injection             injection  injection                               injectionDrum     inhibition             inhibition inhibition                               inhibitionNo.      layer 1  layer 4    layer 6*                               layer 7______________________________________Photo-   19601    19604      19607  19610conductivelayer 4Photo-   19602    19605      19608  19611conductivelayer 5Photo-   19603    19606      19609  19612conductivelayer 6______________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 254__________________________________________________________________________Gas used and its    Substrate    Inner                                      LayerName offlow rate           temperature                           RF power                                 pressure                                      thicknesslayer(SCCM)              (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________SurfaceB.sub.2 H.sub.6 /Ar (20%)              500   250    200   0.35 0.5layer ANH.sub.3      100SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)              100                 ppmSurfaceB.sub.2 H.sub.6 /Ar (20%)              500   250    200   0.35 0.5layer BNH.sub.3      100GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)              100                 ppm__________________________________________________________________________ 
    
     
                       TABLE 255______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    19701     19721     19741   19761layer 1IR absorptive    19702     19722     19742   19762layer 2IR absorptive    19703     19723     19743   19763layer 3IR absorptive    19704     19724     19744   19764layer 4IR absorptive    19705     19725     19745   19765layer 5IR absorptive    19706     19726     19746   19766layer 6IR absorptive    19707     19727     19747   19767layer 7IR absorptive    19708     19728     19748   19768layer 8IR absorptive    19709     19729     19749   19769layer 9IR absorptive    19710     19730     19750   19770layer 10IR absorptive    19711     19731     19751   19771layer 11IR absorptive    19712     19732     19752   19772layer 12IR absorptive    19713     19733     19753   19773layer 13IR absorptive    19714     19734     19754   19774layer 14IR absorptive    19715     19735     19755   19775layer 15IR absorptive    19716     19736     19756   19776layer 16IR absorptive    19717     19737     19757   19777layer 17IR absorptive    19718     19738     19758   19778layer 18IR absorptive    19719     19739     19759   19779layer 19IR absorptive    19720     19740     19760   19780layer 20______________________________________  *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 256______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    19801     19821     19841   19861layer 1IR absorptive    19802     19822     19842   19862layer 2IR absorptive    19803     19823     19843   19863layer 3IR absorptive    19804     19824     19844   19864layer 4IR absorptive    19805     19825     19845   19865layer 5IR absorptive    19806     19826     19846   19866layer 6IR absorptive    19807     19827     19847   19867layer 7IR absorptive    19808     19828     19848   19868layer 8IR absorptive    19809     19829     19849   19869layer 9IR absorptive    19810     19830     19850   19870layer 10IR absorptive    19811     19831     19851   19871layer 11IR absorptive    19812     19832     19852   19872layer 12IR absorptive    19813     19833     19853   19873layer 13IR absorptive    19814     19834     19854   19874layer 14IR absorptive    19815     19835     19855   19875layer 15IR absorptive    19816     19836     19856   19876layer 16IR absorptive    19817     19837     19857   19877layer 17IR absorptive    19818     19838     19858   19878layer 18IR absorptive    19819     19839     19859   19879layer 19IR absorptive    19820     19840     19860   19880layer 20______________________________________  *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 257______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    19901     19921     19941   19961layer 1IR absorptive    19902     19922     19942   19962layer 2IR absorptive    19903     19923     19943   19963layer 3IR absorptive    19904     19924     19944   19964layer 4IR absorptive    19905     19925     19945   19965layer 5IR absorptive    19906     19926     19946   19966layer 6IR absorptive    19907     19927     19947   19967layer 7IR absorptive    19908     19928     19948   19968layer 8IR absorptive    19909     19929     19949   19969layer 9IR absorptive    19910     19930     19950   19970layer 10IR absorptive    19911     19931     19951   19971layer 11IR absorptive    19912     19932     19952   19972layer 12IR absorptive    19913     19933     19953   19973layer 13IR absorptive    19914     19934     19954   19974layer 14IR absorptive    19915     19935     19955   19975layer 15IR absorptive    19916     19936     19956   19976layer 16IR absorptive    19917     19937     19957   19977layer 17IR absorptive    19918     19938     19958   19978layer 18IR absorptive    19919     19938     19959   19979layer 19IR absorptive    19920     19940     19960   19980layer 20______________________________________  *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 258______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    20001     20021     20041   20061layer 1IR absorptive    20002     20022     20042   20062layer 2IR absorptive    20003     20023     20043   20063layer 3IR absorptive    20004     20024     20044   20064layer 4IR absorptive    20005     20025     20045   20065layer 5IR absorptive    20006     20026     20046   20066layer 6IR absorptive    20007     20027     20047   20067layer 7IR absorptive    20008     20028     20048   20068layer 8IR absorptive    20009     20029     20049   20069layer 9IR absorptive    20010     20030     20050   20070layer 10IR absorptive    20011     20031     20051   20071layer 11IR absorptive    20012     20032     20052   20072layer 12IR absorptive    20013     20033     20053   20073layer 13IR absorptive    20014     20034     20054   20074layer 14IR absorptive    20015     20035     20055   20075layer 15IR absorptive    20016     20036     20056   20076layer 16IR absorptive    20017     20037     20057   20078layer 17IR absorptive    20018     20038     20058   20078layer 18IR absorptive    20019     20039     20059   20079layer 19IR absorptive    20020     20040     20060   20080layer 20______________________________________  *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 259______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    20101     20121     20141   20161layer 1IR absorptive    20102     20122     20142   20162layer 2IR absorptive    20103     20123     20143   20163layer 3IR absorptive    20104     20124     20144   20164layer 4IR absorptive    20105     20125     20145   20165layer 5IR absorptive    20106     20126     20146   20166layer 6IR absorptive    20107     20127     20147   20167layer 7IR absorptive    20108     20128     20148   20168layer 8IR absorptive    20109     20129     20149   20169layer 9IR absorptive    20110     20130     20150   20170layer 10IR absorptive    20111     20131     20151   20171layer 11IR absorptive    20112     20132     20152   20172layer 12IR absorptive    20113     20133     20153   20173layer 13IR absorptive    20114     20134     20154   20174layer 14IR absorptive    20115     20135     20155   20175layer 15IR absorptive    20116     20136     20156   20176layer 16IR absorptive    20117     20137     20157   20177layer 17IR absorptive    20118     20138     20158   20178layer 18IR absorptive    20119     20139     20159   20179layer 19IR absorptive    20120     20140     20160   20180layer 20______________________________________  *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 260______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    20201     20221     20241   20261layer 1IR absorptive    20202     20222     20242   20262layer 2IR absorptive    20203     20223     20243   20263layer 3IR absorptive    20204     20224     20244   20264layer 4IR absorptive    20205     20225     20245   20265layer 5IR absorptive    20206     20226     20246   20266layer 6IR absorptive    20207     20227     20247   20267layer 7IR absorptive    20208     20228     20248   20268layer 8IR absorptive    20209     20229     20249   20269layer 9IR absorptive    20210     20230     20250   20270layer 10IR absorptive    20211     20231     20251   20271layer 11IR absorptive    20212     20232     20252   20272layer 12IR absorptive    20213     20233     20253   20273layer 13IR absorptive    20214     20234     20254   20274layer 14IR absorptive    20215     20235     20255   20275layer 15IR absorptive    20216     20236     20256   20276layer 16IR absorptive    20217     20237     20257   20277layer 17IR absorptive    20218     20238     20258   20278layer 18IR absorptive    20219     20239     20259   20279layer 19IR absorptive    20220     20240     20260   20280layer 20______________________________________  *surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 261__________________________________________________________________________    Gas used and its     Substrate    Inner                                      LayerDrum    flow rate            temperature                           RF power                                 pressure                                      thicknessNo. (SCCM)               (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________20301    B.sub.2 H.sub.6 /Ar (20%)             500    250    200   0.35 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             100 ppm    NH.sub.3      10020302    B.sub.2 H.sub.6 /Ar (20%)             500    250    200   0.40 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             50  ppm    H.sub.2       100    NH.sub.3      10020303    B.sub.2 H.sub.6 /Ar (20%)             500    250    200   0.35 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             100 ppm    NH.sub.3      100    Bias voltage of             -150                 V    the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 262__________________________________________________________________________    Gas used and its     Substrate    Inner                                      LayerDrum    flow rate            temperature                           RF power                                 pressure                                      thicknessNo. (SCCM)               (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________20401    B.sub.2 H.sub.6 /Ar (20%)             500    250    200   0.35 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             100 ppm    NH.sub.3      10020402    B.sub.2 H.sub.6 /Ar (20%)             500    250    200   0.40 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             50  ppm    H.sub.2       100    NH.sub.3      10020403    B.sub.2 H.sub.6 /Ar (20%)             500    250    200   0.35 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             100 ppm    NH.sub.3      100    Bias voltage of             -150                 V    the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 263__________________________________________________________________________    Gas used and its     Substrate    Inner                                      LayerDrum    flow rate            temperature                           RF power                                 pressure                                      thicknessNo. (SCCM)               (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________20501    B.sub.2 H.sub.6 /Ar (20%)             500    250    200   0.35 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             100 ppm    NH.sub.3      10020502    B.sub.2 H.sub.6 /Ar (20%)             500    250    200   0.40 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             50  ppm    H.sub.2       100    NH.sub.3      10020503    B.sub.2 H.sub.6 /Ar (20%)             500    250    200   0.35 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             100 ppm    NH.sub.3      100    Bias voltage of             -150                 V    the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 264__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerInter- SiH.sub.4     10    250    150   0.35 0.3mediate CH.sub.4      400layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 265 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)               100                  ppmlayer NO            4Surface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 265 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)               100                  ppmlayer NO            4Surface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 266______________________________________ Initial                             Increase electri-                Defec-      ofDrum  fication Residual       tive  Image defectiveNo.   efficiency          voltage  Ghost image flow  image______________________________________(a)   ○ ⊚                   ○                         ⊚                               ⊚                                     ○(b)   ○ ⊚                   ○                         ⊚                               ⊚                                     ○______________________________________          Break           Degree of                                  Degree ofDrum  Surface  down    Abrasion                          background                                  residualNo.   abrasion voltage resistance                          fogginess                                  stress______________________________________(a)   ○ ○                  ○                          ⊚                                  ⊚(b)   ○ ○                  ○                          ⊚                                  ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 267 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)               100                  ppmlayer NO            4Surface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.40 0.5layer H.sub.2       100 NH.sub.3      300 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               50 ppm__________________________________________________________________________ 
    
     
                                           TABLE 267 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    250   0.35 20conductive B.sub.2 H.sub.6 (against SiH.sub.4)               100                  ppmlayer NO            4Surface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.40 0.5layer H.sub.2       100 NH.sub.3      300 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               50 ppm__________________________________________________________________________ 
    
     
                       TABLE 268______________________________________ Initial                             Increase electri-                Defec-      ofDrum  fication Residual       tive  Image defectiveNo.   efficiency          voltage  Ghost image flow  image______________________________________(a)   ○ ⊚                   ○                         ⊚                               ⊚                                     ○(b)   ○ ⊚                   ○                         ⊚                               ⊚                                     ○______________________________________          Break           Degree of                                  Degree ofDrum  Surface  down    Abrasion                          background                                  residualNo.   abrasion voltage resistance                          fogginess                                  stress______________________________________(a)   ○ ○                  ○                          ⊚                                  ⊚(b)   ○ ○                  ○                          ⊚                                  ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                       TABLE 269______________________________________ Initial                             Increase electri-                Defec-      ofDrum  fication Residual       tive  Image defectiveNo.   efficiency          voltage  Ghost image flow  image______________________________________(a)   ○ ⊚                   ○                         ⊚                               ⊚                                     ○(b)   ○ ⊚                   ○                         ⊚                               ⊚                                     ○______________________________________          Break           Degree of                                  Degree ofDrum  Surface  down    Abrasion                          background                                  residualNo.   abrasion voltage resistance                          fogginess                                  stress______________________________________(a)   ○ ○                  ○                          ⊚                                  ⊚(b)   ○ ○                  ○                          ⊚                                  ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 270 (a)__________________________________________________________________________                     Substrate    Inner                                       LayerName of Gas used and its    temperature                            RF power                                  pressure                                       thicknesslayer flow rate (SCCM)    (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 270 (b)__________________________________________________________________________                     Substrate    Inner                                       LayerName of Gas used and its    temperature                            RF power                                  pressure                                       thicknesslayer flow rate (SCCM)    (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition PH.sub.3 (against SiH.sub.4)               800                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 271______________________________________ Initial                             Increase electri-                Defec-      ofDrum  fication Residual       tive  Image defectiveNo.   efficiency          voltage  Ghost image flow  image______________________________________(a)   ⊚          ⊚                   ○                         ⊚                               ⊚                                     ○(b)   ⊚          ⊚                   ○                         ⊚                               ⊚                                     ○______________________________________          Break           Degree of                                  Degree ofDrum  Surface  down    Abrasion                          background                                  residualNo.   abrasion voltage resistance                          fogginess                                  stress______________________________________(a)   ○ ○                  ○                          ⊚                                  ⊚(b)   ○ ○                  ○                          ⊚                                  ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 272 (a)__________________________________________________________________________                    Substrate    Inner                                      LayerName of Gas used and its   temperature                           RF power                                 pressure                                      thicknesslayer flow rate (SCCM)   (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________Photo- SiH.sub.4     200  250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500  250    100   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100 ppm__________________________________________________________________________ 
    
     
                                           TABLE 272 (b)__________________________________________________________________________                    Substrate    Inner                                      LayerName of Gas used and its   temperature                           RF power                                 pressure                                      thicknesslayer flow rate (SCCM)   (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________Photo- SiH.sub.4     200  250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500  250    100   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100 ppm__________________________________________________________________________ 
    
     
                       TABLE 273______________________________________ Initial                             Increase electri-                Defec-      ofDrum  fication Residual       tive  Image defectiveNo.   efficiency          voltage  Ghost image flow  image______________________________________(a)   ⊚          ⊚                   ○                         ⊚                               ⊚                                     ○(b)   ⊚          ⊚                   ○                         ⊚                               ⊚                                     ○______________________________________          Break           Degree of                                  Degree ofDrum  Surface  down    Abrasion                          background                                  residualNo.   abrasion voltage resistance                          fogginess                                  stress______________________________________(a)   ○ ○                  ○                          ⊚                                  ⊚(b)   ○ ○                  ○                          ⊚                                  ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 274 (a)__________________________________________________________________________                     Substrate    Inner                                       LayerName of Gas used and its    temperature                            RF power                                  pressure                                       thicknesslayer flow rate (SCCM)    (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________IR    SiH.sub.4     100   250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4     50 B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppm NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 274 (b)__________________________________________________________________________                     Substrate    Inner                                       LayerName of Gas used and its    temperature                            RF power                                  pressure                                       thicknesslayer flow rate (SCCM)    (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________IR    SiH.sub.4     100   250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4     50 PH.sub.3 (against SiH.sub.4)               800                  ppm NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 275______________________________________ Initial                             Increase electri-                Defec-      ofDrum  fication Residual       tive  Image defectiveNo.   efficiency          voltage  Ghost image flow  image______________________________________(a)   ○ ⊚                   ○                         ⊚                               ⊚                                     ○(b)   ○ ⊚                   ○                         ⊚                               ⊚                                     ○______________________________________          Break           Degree of                                  Degree ofDrum  Surface  down    Abrasion                          background                                  residualNo.   abrasion voltage resistance                          fogginess                                  stress______________________________________(a)   ○ ○                  ○                          ⊚                                  ⊚(b)   ○ ○                  ○                          ⊚                                  ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 276 (a)__________________________________________________________________________                     Substrate    Inner                                       LayerName of Gas used and its    temperature                            RF power                                  pressure                                       thicknesslayer flow rate (SCCM)    (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4     20    250    100   0.25 0.5layer N.sub.2       100Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 276 (b)__________________________________________________________________________                     Substrate    Inner                                       LayerName of Gas used and its    temperature                            RF power                                  pressure                                       thicknesslayer flow rate (SCCM)    (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4     20    250    100   0.25 0.5layer N.sub.2       100Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 277______________________________________ Initial                             Increase electri-                Defec-      ofDrum  fication Residual       tive  Image defectiveNo.   efficiency          voltage  Ghost image flow  image______________________________________(a)   ⊚          ⊚                   ○                         ⊚                               ⊚                                     ○(b)   ⊚          ⊚                   ○                         ⊚                               ⊚                                     ○______________________________________          Break           Degree of                                  Degree ofDrum  Surface  down    Abrasion                          background                                  residualNo.   abrasion voltage resistance                          fogginess                                  stress______________________________________(a)   ○ ○                  ○                          ⊚                                  ⊚(b)   ○ ○                  ○                          ⊚                                  ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 278 (a)__________________________________________________________________________                     Substrate    Inner                                       LayerName of Gas used and its    temperature                            RF power                                  pressure                                       thicknesslayer flow rate (SCCM)    (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________IR    SiH.sub.4     100   250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4     50 B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppm NO            10Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 278 (b)__________________________________________________________________________                     Substrate    Inner                                       LayerName of Gas used and its    temperature                            RF power                                  pressure                                       thicknesslayer flow rate (SCCM)    (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________IR    SiH.sub.4     100   250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4     50 PH.sub.3 (against SiH.sub.4)               800                  ppm NO            10Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition PH.sub.3 (against SiH.sub.4)               800                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 279______________________________________ Initial                             Increase electri-                Defec-      ofDrum  fication Residual       tive  Image defectiveNo.   efficiency          voltage  Ghost image flow  image______________________________________(a)   ⊚          ⊚                   ○                         ⊚                               ⊚                                     ○(b)   ⊚          ⊚                   ○                         ⊚                               ⊚                                     ○______________________________________          Break          Degree of                                 Degree ofDrum  Surface  down    Abrasion                         background                                 residualNo.   abrasion voltage resistance                         fogginess                                 stress______________________________________(a)   ○ ○                  ○                         ⊚                                 ⊚(b)   ○ ○                  ○                         ⊚                                 ⊚______________________________________ ⊚:Excellent  ○ :Good 
    
     
                                           TABLE 280 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4      20   250     50   0.05 0.5layer N.sub.2       10Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 280 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4      20   250     50   0.05 0.5layer N.sub.2       10Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition PH 3 (against SiH.sub.4)               800                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 281______________________________________ Initial                             Increase electri-                Defec-      ofDrum  fication Residual       tive  Image defectiveNo.   efficiency          voltage  Ghost image flow  image______________________________________(a)   ⊚          ⊚                   ○                         ⊚                               ⊚                                     ○(b)   ⊚          ⊚                   ○                         ⊚                               ⊚                                     ○______________________________________          Break          Degree of                                 Degree ofDrum  Surface  down    Abrasion                         background                                 residualNo.   abrasion voltage resistance                         fogginess                                 stress______________________________________(a)   ○ ○                  ○                         ⊚                                 ⊚(b)   ○ ○                  ○                         ⊚                                 ⊚______________________________________ ⊚:Excellent  ○ :Good 
    
     
                                           TABLE 282 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4      20   250     50   0.05 0.5layer N.sub.2       10IR    SiH.sub.4     100   250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4     50 B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppm NO            10Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 282 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4      20   250     50   0.05 0.5layer N.sub.2       10IR    SiH.sub.4     100   250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4     50 PH.sub.3 (against SiH.sub.4)               800                  ppm NO            10Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition PH.sub.3 (against SiH.sub.4)               800                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                       TABLE 283______________________________________ Initial                             Increase electri-                Defec-      ofDrum  fication Residual       tive  Image defectiveNo.   efficiency          voltage  Ghost image flow  image______________________________________(a)   ⊚          ⊚                   ○                         ⊚                               ⊚                                     ○(b)   ⊚          ⊚                   ○                         ⊚                               ⊚                                     ○______________________________________          Break          Degree of                                 Degree ofDrum  Surface  down    Abrasion                         background                                 residualNo.   abrasion voltage resistance                         fogginess                                 stress______________________________________(a)   ○ ○                  ○                         ⊚                                 ⊚(b)   ○ ○                  ○                         ⊚                                 ⊚______________________________________ ⊚:Excellent  ○ :Good 
    
     
                                           TABLE 284__________________________________________________________________________Gas used and its                Substrate    Inner                                  LayerDrum flow rate       temperature                       RF power                             pressure                                  thicknessNo.  (SCCM)          (°C.)                       (W)   (Torr)                                  (μm)__________________________________________________________________________21901SiH.sub.4 200   250    300   0.40 20He        200B.sub.2 H.sub.6 (against SiH.sub.4)          100             ppmNO        421902SiH.sub.4 150   250    350   0.40 20SiF.sub.4 50H.sub.2   200B.sub.2 H.sub.6 (against SiH.sub.4)          100             ppmNO        621903SiH.sub.4 200   250    300   0.40 20H.sub.2   20021904SiH.sub.4 200   250    250   0.40 20Ar        20021905SiH.sub.4 150   250    350   0.40 20SiF.sub.4 50H.sub.2   200 21906*SiH.sub.4 200   250    300   0.40 20He        200B.sub.2 H.sub.6 (against SiH.sub.4)          100             ppmNO        4 21907*SiH.sub.4 150   250    350   0.40 20SiF.sub.4 50H.sub.2   200B.sub.2 H.sub.6 (against SiH.sub.4)          100             ppmNO        6 21908*SiH.sub.4 200   250    300   0.40 20H.sub.2   200 21909*SiH.sub.4 200   250    250   0.40 20Ar        200 21910*SiH.sub.4 150   250    350   0.40 20SiF.sub.4 50H.sub.2   200__________________________________________________________________________ *surface layer followed Table 265 (b) markless case: followed Table 265 (a) 
    
     
                                           TABLE 285__________________________________________________________________________Gas used and its                Substrate    Inner                                  LayerDrum flow rate       temperature                       RF power                             pressure                                  thicknessNo.  (SCCM)          (°C.)                       (W)   (Torr)                                  (μm)__________________________________________________________________________22001SiH.sub.4 200   250    300   0.40 20He        200B.sub.2 H.sub.6 (against SiH.sub.4)          100             ppmNO        422002SiH.sub.4 150   250    350   0.40 20SiF.sub.4 50H.sub.2   200B.sub.2 H.sub.6 (against SiH.sub.4)          100             ppmNO        622003SiH.sub.4 200   250    300   0.40 20H.sub.2   20022004SiH.sub.4 200   250    250   0.40 20Ar        20022005SiH.sub.4 150   250    350   0.40 20SiF.sub.4 50H.sub.2   200 22006*SiH.sub.4 200   250    300   0.40 20He        200B.sub.2 H.sub.6 (against SiH.sub.4)          100             ppmNO        4 22007*SiH.sub.4 150   250    350   0.40 20SiF.sub.4 50H.sub.2   200B.sub.2 H.sub.6 (against SiH.sub.4)          100             ppmNO        6 22008*SiH.sub.4 200   250    300   0.40 20H.sub.2   200 22009*SiH.sub.4 200   250    250   0.40 20Ar        200 22010*SiH.sub.4 150   250    350   0.40 20SiF.sub.4 50H.sub.2   200__________________________________________________________________________ *surface layer followed Table 267 (b) markless case: followed Table 267 (a) 
    
     
                                           TABLE 286__________________________________________________________________________Gas used and its                Substrate    Inner                                  LayerDrum flow rate       temperature                       RF power                             pressure                                  thicknessNo.  (SCCM)          (°C.)                       (W)   (Torr)                                  (μm)__________________________________________________________________________22101SiH.sub.4 200   250    300   0.40 20He        200B.sub.2 H.sub.6 (against SiH.sub.4)          100             ppmNO        422102SiH.sub.4 150   250    350   0.40 20SiF.sub.4 50H.sub.2   200B.sub.2 H.sub.6 (against SiH.sub.4)          100             ppmNO        622103SiH.sub.4 200   250    300   0.40 20H.sub.2   20022104SiH.sub.4 200   250    250   0.40 20Ar        20022105SiH.sub.4 150   250    350   0.40 20SiF.sub.4 50H.sub.2   200 22106*SiH.sub.4 200   250    300   0.40 20He        200B.sub.2 H.sub.6 (against SiH.sub.4)          100             ppmNO        4 22107*SiH.sub.4 150   250    350   0.40 20SiF.sub.4 50H.sub.2   200B.sub.2 H.sub.6 (against SiH.sub.4)          100             ppmNO        6 22108*SiH.sub.4 200   250    300   0.40 20H.sub.2   200 22109*SiH.sub.4 200   250    250   0.40 20Ar        200 22110*SiH.sub.4 150   250    350   0.40 20SiF.sub.4 50H.sub.2   200__________________________________________________________________________ *surface layer followed Table 265 (b) markless case: followed Table 265 (a) 
    
     
                                           TABLE 287__________________________________________________________________________               Substrate    Inner                                 LayerDrum    Gas used and its               temperature                      RF Power                            pressure                                 thicknessNo. flow rate (SCCM)               (°C.)                      (W)   (Torr)                                 (μm)__________________________________________________________________________22201    SiH.sub.4 100   250    150   0.35 3    H.sub.2   100    B.sub.2 H.sub.6 (against SiH.sub.4)         1000            ppm    GeH.sub.4 10    NO        1022202    SiH.sub.4 80    250    170   0.25 3    SiF.sub.4 20    B.sub.2 H.sub.6 (against SiH.sub.4)         1000            ppm    SnH.sub.4 5    NO        522203    SiH.sub.4 100   250    130   0.25 3    B.sub.2 H.sub.6 (against SiH.sub.4)         800            ppm    NO        4    N.sub.2   4    CH.sub.4  622204*    SiH.sub.4 100   250    150   0.35 3    H.sub.2   100    PH.sub.3 (against SiH.sub.4)         800            ppm22205*    SiH.sub.4 100   250    130   0.25 3    PH.sub.3 (against SiH.sub.4)         800            ppm    GeH.sub.4 10    NO        1022206    SiH.sub.4 100   250    150   0.35 3    H.sub.2   100    B.sub.2 H.sub.6 (against SiH.sub.4)         1000            ppm    NO*       10NO**          10→0***__________________________________________________________________________ *surface layer followed Table 208(b) markless case: followed Table 208(a) *Substrate side 2 μm **Surface layer side 1 μm ***Constantly changed 
    
     
                                           TABLE 288__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5*                          layer 6*                               layer 7__________________________________________________________________________Photo- 22301      22306           22311                22316                     22321                          22326                               22331conductivelayer 1Photo- 22302      22307           22312                22317                     22322                          22327                               22332conductivelayer 2Photo- 22303      22308           22313                22318                     22323                          22328                               22233conductivelayer 3Photo- 22304      22309           22314                22319                     22324                          22329                               22334conductivelayer 5Photo- 22305      22310           22315                22320                     22325                          22330                               22335conductivelayer 6__________________________________________________________________________ *surface layer followed Table 6(b) markless case: followed Table 6(a) 
    
     
                                           TABLE 289__________________________________________________________________________                    Substrate    Inner                                      LayerName ofGas used and its    temperature                           RF power                                 pressure                                      thicknesslayerflow rate (SCCM)    (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________Surface*B.sub.2 H.sub.6 /He (20%)              500   250    100   0.40 0.5layer AH.sub.2       100NH.sub.3      300SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)              50 ppmSurface*B.sub.2 H.sub.6 /He (20%)              500   250    100   0.40 0.5layer BH.sub.2       100NH.sub.3      300GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)              50 ppm__________________________________________________________________________ *each of surface layers A and B is individually used in accordance with the kind of the lower layer 
    
     
                                           TABLE 290__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5*                          layer 6*                               layer 7__________________________________________________________________________Photo- 22401      22407           22413                22419                     22425                          22431                               22437conductivelayer 1Photo- 22402      22408           22414                22420                     22426                          22432                               22438conductivelayer 2Photo- 22403      22409           22415                22421                     22427                          22433                               22439conductivelayer 3Photo- 22404      22410           22416                22422                     22428                          22434                               22440conductivelayer 4Photo- 22405      22411           22417                22423                     22429                          22435                               22441conductivelayer 5Photo- 22406      22412           22418                22424                     22430                          22436                               22442conductivelayer 6__________________________________________________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 291__________________________________________________________________________                    Substrate    Inner                                      LayerName ofGas used and its    temperature                           RF power                                 pressure                                      thicknesslayerflow rate (SCCM)    (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________Surface*B.sub.2 H.sub.6 /He (20%)              500   250    100   0.35 0.5layer ANH.sub.3      100SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)              100                 ppmBias voltage of              +100                 Vthe cylinderSurface*B.sub.2 H.sub.6 /He (20%)              500   250    100   0.35 0.5layer BNH.sub.3      100GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)              100                 ppmBias voltage of              +100                 Vthe cylinder__________________________________________________________________________ *each of surface layers A and B is individually used in accordance with the kind of the lower layer 
    
     
                                           TABLE 292__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5*                          layer 6*                               layer 7__________________________________________________________________________Photo- 22501      22507           22513                22519                     22525                          22531                               22537conductivelayer 1Photo- 22502      22508           22514                22520                     22526                          22532                               22538conductivelayer 2Photo- 22503      22509           22515                22521                     22527                          22533                               22539conductivelayer 3Photo- 22504      22510           22516                22522                     22528                          22534                               22540conductivelayer 4Photo- 22505      22511           22517                22523                     22529                          22535                               22541conductivelayer 5Photo- 22506      22512           22518                22524                     22530                          22536                               22542conductivelayer 6__________________________________________________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 293______________________________________Photo-               Photo-           Photo-conduc-    Photo-    conduc-  Photo-  conduc-tive       conductive                tive     conductive                                 tiveLayer 1    Layer 2   Layer 3  Layer 5 Layer 6______________________________________Drum  22601    22602     22603  22604   22605No.   22606*   22607*    22608* 22609*  22610*______________________________________ *Surface layer followed Table 272(b) Markless case: followed Table 272(a) 
    
     
                                           TABLE 294__________________________________________________________________________Photo-    Photo-           Photo-                 Photo-                       Photo-                             Photo-conductive     conductive           conductive                 conductive                       conductive                             conductivelayer 1   layer 2           layer 3                 layer 4                       layer 5                             layer 6__________________________________________________________________________Drum    22701 22702 22703 22704 22705 22706No. 22707*     22708*           22709*                 22710*                       22711*                             22712*__________________________________________________________________________ *surface layer B was used. markless case: surface layer A was used. 
    
     
                                           TABLE 295__________________________________________________________________________Photo-    Photo-           Photo-                 Photo-                       Photo-                             Photo-conductive     conductive           conductive                 conductive                       conductive                             conductivelayer 1   layer 2           layer 3                 layer 4                       layer 5                             layer 6__________________________________________________________________________Drum    22801 22802 22803 22804 22805 22806No. 22807*     22808*           22809*                 22810*                       22811*                             22812*__________________________________________________________________________ *surface layer B was used. markless case: surface layer A was used. 
    
     
                       TABLE 296______________________________________          Drum          No.______________________________________IR Absorptive    22901   22920*Layer 1IR Absorptive    22902   22921*Layer 2IR Absorptive    22903   22922*Layer 3IR Absorptive    22904   22923*Layer 4IR Absorptive    22905   22924*Layer 5IR Absorptive    22906   --Layer 6IR Absorptive    22907   --Layer 7IR Absorptive    22908   --Layer 8IR Absorptive    22909   --Layer 9IR Absorptive    22910   --Layer 10IR Absorptive    22911   --Layer 11IR Absorptive    22912   --Layer 12IR Absorptive    22913   --Layer 13IR Absorptive    22914   --Layer 14IR Absorptive    22915   --Layer 15IR Absorptive    22916   --Layer 17IR Absorptive    22917   22925*Layer 18IR Absorptive    22918   22926*Layer 19IR Absorptive    22919   22927*Layer 20______________________________________ *Surface layer followed Table 274(b) Markless case: followed 274(a) 
    
     
                                           TABLE 297__________________________________________________________________________   Photo-         Photo-               Photo-                     Photo-                           Photo-Drum    conductive         conductive               conductive                     conductive                           conductiveNo.     layer 1         layer 2               layer 3                     layer 5                           layer 6__________________________________________________________________________IR aborptive   23001 23021 23041 23061 23081layer 1IR absorptive   23002 23022 23042 23062 23082layer 2IR absorptive   23003 23023 23043 23063 23083layer 3IR absorptive   23004 23024 23044 23064 23084layer 4IR absorptive   23005 23025 23045 23065 23085layer 5IR absorptive   23006 23026 23046 23066 23086layer 6IR absorptive   23007 23027 23047 23067 23087layer 7IR absorptive   23008 23028 23048 23068 23088layer 8IR absorptive   23009 23029 23049 23069 23089layer 9IR absorptive   23010 23030 23050 23070 23090layer 10IR absorptive   23011 23031 23051 23071 23091layer 11*IR absorptive   23012 23032 23052 23072 23092layer 12*IR absorptive   23013 23033 23053 23073 23093layer 13*IR absorptive   23014 23034 23054 23074 23094layer 14*IR absorptive   23015 23035 23055 23075 23095layer 15*IR absorptive   23016 23036 23056 23076 23096layer 16*IR absorptive   23017 23037 23057 23077 23097layer 17*IR absorptive   23018 23038 23058 23078 23098layer 18IR absorptive   23019 23039 23059 23079 23099layer 19IR absorptive   23020 23040 23060 23080 230100layer 20__________________________________________________________________________  *surface layer followed Table 274(b) markless case: followed Table 274(a) 
    
     
                                           TABLE 298__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-                                Photo-Drum   conductive        conductive              conductive                    conductive                          conductive                                conductiveNo.    layer 1        layer 2              layer 3                    layer 4                          layer 5                                layer 6__________________________________________________________________________IR absorptive  23101 23121 23141 23161 23181 231101layer 1IR absorptive  23102 23122 23142 23162 23182 231102layer 2IR absorptive  23103 23123 23143 23163 23183 231103layer 3IR absorptive  23104 23124 23144 23164 23184 231104layer 4IR absorptive  23105 23125 23145 23165 23185 231105layer 5IR absorptive  23106 23126 23146 23166 23186 231106layer 6IR absorptive  23107 23127 23147 23167 23187 231107layer 7IR absorptive  23108 23128 23148 23168 23188 231108layer 8IR absorptive  23109 23129 23149 23169 23189 231109layer 9IR absorptive  23110 23130 23150 23170 23190 231110layer 10IR absorptive  23111 23131 23151 23171 23191 231111layer 11*IR absorptive  23112 23132 23152 23172 23192 231112layer 12*IR absorptive  23113 23133 23153 23173 23193 231113layer 13*IR absorptive  23114 23134 23154 23174 23194 231114layer 14*IR absorptive  23115 23135 23155 23175 23195 231115layer 15*IR absorptive  23116 23136 23156 23176 23196 231116layer 16IR absorptive  23117 23137 23157 23177 23197 231117layer 17*IR absorptive  23118 23138 23158 23178 23198 231118layer 18IR absorptive  23119 23139 23159 23179 23199 231119layer 19IR absorptive  23120 23140 23160 23180 231100                                231120layer 20__________________________________________________________________________  *surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 299__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-                                Photo-Drum   conductive        conductive              conductive                    conductive                          conductive                                conductiveNo.    layer 1        layer 2              layer 3                    layer 4                          layer 5                                laeyr 6__________________________________________________________________________IR absorptive  23201 23221 23241 23261 23281 232101layer 1IR absorptive  23202 23222 23242 23262 23282 232102layer 2IR absorptive  23203 23223 23243 23263 23283 232103layer 3IR absorptive  23204 23224 23244 23264 23284 232104layer 4IR absorptive  23205 23225 23245 23265 23285 232105layer 5IR absorptive  23206 23226 23246 23266 23286 232106layer 6IR absorptive  23207 23227 23247 23267 23287 232107layer 7IR absorptive  23208 23228 23248 23268 23288 232108layer 8IR absorptive  23209 23229 23249 23269 23289 232109layer 9IR absorptive  23210 23230 23250 23270 23290 232110layer 10IR absorptive  23211 23231 23251 23271 23291 232111layer 11*IR absorptive  23212 23232 23252 23272 23292 232112layer 12*IR absorptive  23213 23233 23253 23273 23293 232113layer 13*IR absorptive  23214 23234 23254 23274 23294 232114layer 14*IR absorptive  23215 23235 23255 23275 23295 232115layer 15*IR absorptive  23216 23236 23256 23276 23296 232116layer 16*IR absorptive  23217 23237 23257 23277 23297 232117layer 17*IR absorptive  23218 23238 23258 23278 23298 232118layer 18IR absorptive  23219 23239 23259 23279 23299 232119layer 19IR absorptive  23220 23240 23260 23280 232100                                232120layer 20__________________________________________________________________________  *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 300______________________________________Contact           Contact  ContactLayer 2           Layer 3  Layer 4______________________________________Drum    23301         23302    23303No.     23304*        23305*   23306*______________________________________ *Surface layer followed Table 276(b) Markless case: followed Table 276(a) 
    
     
                       TABLE 301______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-   23401      23407*   23413   23419conductivelayer 1Photo-   23402     23408      23414* 23420conductivelayer 2Photo-    23403*   23409     23415   23421conductivelayer 3Photo-   23404     23410     23416    23422*conductivelayer 4Photo-   23405     23411      23417* 23423conductivelayer 5Photo-   23406      23412*   23418   23424conductivelayer 6______________________________________ *surface layer followed Table 276(b) markless case: followed Table 276(a) 
    
     
                       TABLE 302______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-   23501     23507      23513* 23519conductivelayer 1Photo-   23502      23508*   23514   23520conductivelayer 2Photo-   23503     23509     23515    23521*conductivelayer 3Photo-    23504*   23510     23516   23522conductivelayer 4Photo-   23505      23511*   23517   23523conductivelayer 5Photo-   23506     23512      23518* 23524conductivelayer 6______________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 303______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-    23601*   23607     23613   23619conductivelayer 1Photo-   23602     23608      23614* 23620conductivelayer 2Photo-   23603     23609     23615    23621*conductivelayer 3Photo-   23604      23610*   23616   23622conductivelayer 4Photo-   23605     23611     23617    23623*conductivelayer 5Photo-    23606*   23612     23618   23624conductivelayer 6______________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 304______________________________________          Drum          No.______________________________________IR absorptive    23701   23721layer 1                  *IR absorptive    23702   23722layer 2                  *IR absorptive    23703   23723layer 3                  *IR absorptive    23704   23724layer 4                  *IR absorptive    23705   23726layer 5                  *IR absorptive    23706   23726layer 6                  *IR absorptive    23707   23727layer 7                  *IR absorptive    23708   23728layer 8                  *IR absorptive    23709   23729layer 9                  *IR absorptive    23710   23730layer 10                 *IR absorptive    23711   23731layer 11                 *IR absorptive    23712   23732layer 12                 *IR absorptive    23713   23733layer 13                 *IR absorptive    23714   23734layer 14                 *IR absorptive    23715   23735layer 15                 *IR absorptive    23717   23737layer 17                 *IR absorptive    23718   23738layer 18                 *IR absorptive    23719   23739layer 19                 *IR absorptive    23720   23740layer 20                 *______________________________________  *Charge injection inhibition layer and surface layer followed Table 278(b) markless case: followed Table 178(a) 
    
     
                       TABLE 305______________________________________      Photo-      Photo-    Photo-Drum       conductive  conductive                            conductiveNo.        layer 4     layer 5*  layer 7______________________________________IR absorptive      23801       23821     23841layer 1IR absorptive      23802       23822     23842layer 2IR absorptive      23803       23823     23843layer 3IR absorptive      23804       23824     23844layer 4IR absorptive      23805       23825     23845layer 5IR absorptive      23806       23826     23846layer 6IR absorptive      23807       23827     23847layer 7IR absorptive      23808       23828     23848layer 8IR absorptive      23809       23829     23849layer 9IR absorptive      23810       23830     23840layer 10IR absorptive      23811       23831     23851layer 11IR absorptive      23812       23832     23852layer 12IR absorptive      23813       23833     23853layer 13IR absorptive      23814       23834     23854layer 14IR absorptive      23815       23835     23855layer 15IR absorptive      23816       23836     23856layer 16IR absorptive      23817       23837     23857layer 17IR absorptive      23818       23838     23858layer 18IR absorptive      23819       23839     23859layer 19IR absorptive      23820       23840     23860layer 20______________________________________ *: surface layer followed Table 278(b) markless case: followed Table 278(a) 
    
     
                       TABLE 306______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    23901     23921     23941   23961layer 1IR absorptive    23902     23922     23942   23962layer 2IR absorptive    23903     23923     23943   23963layer 3IR absorptive    23904     23924     23944   23964layer 4IR absorptive    23905     23925     23945   23965layer 5IR absorptive    23906     23926     23946   23966layer 6IR absorptive    23907     23927     23947   23967layer 7IR absorptive    23908     23928     23948   23968layer 8IR absorptive    23909     23929     23949   23969layer 9IR absorptive    23910     23930     23950   23970layer 10IR absorptive    23911     23931     23951   23971layer 11IR absorptive    23912     23932     23952   23972layer 12IR absorptive    23913     23933     23953   23973layer 13IR absorptive    23914     23934     23954   23974layer 14IR absorptive    23915     23935     23955   23975layer 15IR absorptive    23916     23936     23956   23976layer 16IR absorptive    23917     23937     23957   23977layer 17IR absorptive    23918     23938     23958   23978layer 18IR absorptive    23919     23939     23959   23979layer 19IR absorptive    23920     23940     23960   23980layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 307______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    24001     24021     24041   24061layer 1IR absorptive    24002     24022     24042   24062layer 2IR absorptive    24003     24023     24043   24063layer 3IR absorptive    24004     24024     24044   24064layer 4IR absorptive    24005     24025     24045   24065layer 5IR absorptive    24006     24026     24046   24066layer 6IR absorptive    24007     24027     24047   24067layer 7IR absorptive    24008     24028     24048   24068layer 8IR absorptive    24009     24029     24049   24069layer 9IR absorptive    24010     24030     24050   24070layer 10IR absorptive    24011     24031     24051   24071layer 11IR absorptive    24012     24032     24052   24072layer 12IR absorptive    24013     24033     24053   24073layer 13IR absorptive    24014     24034     24054   24074layer 14IR absorptive    24015     24035     24055   24075layer 15IR absorptive    24016     24036     24056   24076layer 16IR absorptive    24017     24037     24057   24077layer 17IR absorptive    24018     24038     24058   24078layer 18IR absorptive    24019     24039     24059   24079layer 19IR absorptive    24020     24040     24060   24080layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 308__________________________________________________________________________Contact  Contact         Contact              Contact                   Contact                        Contact                             ContactLayer 1  Layer 2         Layer 3              Layer 4                   Layer 6                        Layer 7                             Layer 8__________________________________________________________________________Drum    24101    24102         24103              24104                   24105                        24106                             24107No. 24108*    24109*         24110*              24111*                   24112*                        24113*                             24114*__________________________________________________________________________ *Charge injection inhibition layer and surface layer followed Table 280(b Markless case: followed Table 280(a) 
    
     
                                           TABLE 309__________________________________________________________________________ Charge      Charge            Charge                 Charge                       Charge                            Charge injection      injection            injection                 injection                       injection                            injectionDrum  inhibition      inhibition            inhibition                 inhibition                       inhibition                            inhibitionNo.   layer 2      layer 3            layer 4                 layer 5*                       layer 6*                            layer 7__________________________________________________________________________Contact 24201      24209 24217                 24225 24233                            24241layer 1Contact 24202      24210 24218                 24226 24234                            24242layer 2Contact 24203      24211 24219                 24227 24235                            24243layer 3Contact 24204      24212 24220                 24228 24236                            24244layer 4Contact 24205      24213 24221                 24229 24237                            24245layer 5Contact 24206      24214 24222                 24230 24238                            24246layer 6Contact 24207      24215 24223                 24231 24239                            24247layer 7Contact 24208      24216 24224                 24232 24240                            24248layer 8__________________________________________________________________________ *surface layer followed Table 280(b) markless case: followed Table 280(a) 
    
     
                                           TABLE 310__________________________________________________________________________Charge     Charge          Charge               Charge                    Charge                         Charge                              Chargeinjection     injection          injection               injection                    injection                         injection                              injectionDrum inhibition     inhibition          inhibition               inhibition                    inhibition                         inhibition                              inhibitonNo.  layer 1     layer 2          layer 3               layer 4                    layer 5*                         layer 6*                              layer 7__________________________________________________________________________Contact24301     24309          24317               24325                    24333                         24341                              24349layer 1Contact24302     24310          24318               24326                    24334                         24342                              24350layer 2Contact24303     24311          24319               24327                    24335                         24343                              24351layer 3Contact24304     24312          24320               24328                    24336                         24344                              24352layer 4Contact24305     24313          24321               24329                    24337                         24345                              24353layer 5Contact24306     24314          24322               24330                    24338                         24346                              24354layer 6Contact24307     24315          24323               24331                    24339                         24347                              24355layer 7Contact24308     24316          24324               24332                    24340                         24348                              24356layer 8__________________________________________________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 311__________________________________________________________________________Charge     Charge          Charge               Charge                    Charge                         Charge                              Chargeinjection     injection          injection               injection                    injection                         injection                              injectionDrum inhibition     inhibition          inhibition               inhibition                    inhibition                         inhibition                              inhibitionNo.  layer 1     layer 2          layer 3               layer 4                    layer 5*                         layer 6*                              layer 7__________________________________________________________________________Contact24401     24409          24417               24425                    24433                         24441                              24449layer 1Contact24402     24410          24418               24426                    24434                         24442                              24450layer 2Contact24403     24411          24419               24427                    24435                         24443                              24451layer 3Contact24404     24412          24420               24428                    24436                         24444                              24452layer 4Contact24405     24413          24421               24429                    24437                         24445                              24453layer 5Contact24406     24414          24422               24430                    24438                         24446                              24454layer 6Contact24407     24415          24423               24431                    24439                         24447                              24455layer 7Contact24408     24416          24424               24432                    24440                         24448                              24456layer 8__________________________________________________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 312______________________________________  Charge     Charge   Charge  injection  injection                      injection  inhibition inhibition                      inhibition  layer 4    layer 6* layer 7______________________________________Drum     24501        24502    24503No.______________________________________ *surface layer followed Table 282 (b) markless case: followed Table 282 (a) 
    
     
                       TABLE 313______________________________________    Charge    Charge    Charge  Charge    injection injection injection                                injectionDrum     inhibition              inhibition                        inhibition                                inhibitionNo.      layer 1   layer 4   layer 6*                                layer 7______________________________________Photo-   24601     24603     24605   24607conductivelayer 5Photo-   24602     24604     24606   24608conductivelayer 6______________________________________ *surface layer followed Table 282 (b) markless case: followed Table 282 (a) 
    
     
                       TABLE 314______________________________________    Charge    Charge    Charge  Charge    injection injection injection                                injectionDrum     inhibition              inhibition                        inhibition                                inhibitionNo.      layer 1   layer 4   layer 6*                                layer 7______________________________________Photo-   24701     24704     24707   24710conductivelayer 4Photo-   24702     24705     24708   24711conductivelayer 5Photo-   24703     24706     24709   24712conductivelayer 6______________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 315______________________________________    Charge    Charge    Charge  Charge    injection injection injection                                injectionDrum     inhibition              inhibition                        inhibition                                inhibitionNo.      layer 1   layer 4   layer 6*                                layer 7______________________________________Photo-   24801     24804     24807   24810conductivelayer 4Photo-   24802     24805     24808   24811conductivelayer 5Photo-   24803     24806     24809   24812conductivelayer 6______________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 316__________________________________________________________________________                    Substrate    Inner                                      LayerName ofGas used and its    temperature                           RF power                                 pressure                                      thicknesslayerflow rate (SCCM)    (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________SurfaceB.sub.2 H.sub.6 /He (20%)              500   250    100   0.35 0.5layer ANH.sub.3      100SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)              100                 ppmSurfaceB.sub.2 H.sub.6 /He (20%)              500   250    100   0.35 0.5layer BNH.sub.3      100GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)              100                 ppm__________________________________________________________________________ 
    
     
                       TABLE 317______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    24901     24921     24941   24961layer 1IR absorptive    24902     24922     24942   24962layer 2IR absorptive    24903     24923     24943   24963layer 3IR absorptive    24904     24924     24944   24964layer 4IR absorptive    24905     24925     24945   24965layer 5IR absorptive    24906     24926     24946   24966layer 6IR absorptive    24907     24927     24947   24967layer 7IR absorptive    24908     24928     24948   24968layer 8IR absorptive    24909     24929     24949   24969layer 9IR absorptive    24910     24930     24950   24970layer 10IR absorptive    24911     24931     24951   24971layer 11IR absorptive    24912     24932     24952   24972layer 12IR absorptive    24913     24933     24953   24973layer 13IR absorptive    24914     24934     24954   24974layer 14IR absorptive    24915     24935     24955   24975layer 15IR absorptive    24916     24936     24956   24976layer 16IR absorptive    24917     24937     24957   24977layer 17IR absorptive    24918     24938     24958   24978layer 18IR absorptive    24919     24939     24959   24979layer 19IR absorptive    24920     24940     24960   24980layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 318______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    25001     25021     25041   25061layer 1IR absorptive    25002     25022     25042   25062layer 2IR absorptive    25003     25023     25043   25063layer 3IR absorptive    25004     25024     25044   25064layer 4IR absorptive    25005     25025     25045   25065layer 5IR absorptive    25006     25026     25046   25066layer 6IR absorptive    25007     25027     25047   25067layer 7IR absorptive    25008     25028     25048   25068layer 8IR absorptive    25009     25029     25049   25069layer 9IR absorptive    25010     25030     25050   25070layer 10IR absorptive    25011     25031     25051   25071layer 11IR absorptive    25012     25032     25052   25072layer 12IR absorptive    25013     25033     25053   25073layer 13IR absorptive    25014     25034     25054   25074layer 14IR absorptive    25015     25035     25055   25075layer 15IR absorptive    25016     25036     25056   25076layer 16IR absorptive    25017     25037     25057   25077layer 17IR absorptive    25018     25038     25058   25078layer 18IR absorptive    25019     25039     25059   25079layer 19IR absorptive    25020     25040     25060   25080layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 319______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    25101     25121     25141   25161layer 1IR absorptive    25102     25122     25142   25162layer 2IR absorptive    25103     25123     25143   25163layer 3IR absorptive    25104     25124     25144   25164layer 4IR absorptive    25105     25125     25145   25165layer 5IR absorptive    25106     25126     25146   25166layer 6IR absorptive    25107     25127     25147   25167layer 7IR absorptive    25108     25128     25148   25168layer 8IR absorptive    25109     25129     25149   25169layer 9IR absorptive    25110     25130     25150   25170layer 10IR absorptive    25111     25131     25151   25171layer 11IR absorptive    25112     25132     25152   25172layer 12IR absorptive    25113     25133     25153   25173layer 13IR absorptive    25114     25134     25154   25174layer 14IR absorptive    25115     25135     25155   25175layer 15IR absorptive    25116     25136     25156   25176layer 16IR absorptive    25117     25137     25157   25177layer 17IR absorptive    25118     25138     25158   25178layer 18IR absorptive    25119     25138     25159   25179layer 19IR absorptive    25120     25140     25160   25180layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 320______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    25201     25221     25241   25261layer 1IR absorptive    25202     25222     25242   25262layer 2IR absorptive    25203     25223     25243   25263layer 3IR absorptive    25204     25224     25244   25264layer 4IR absorptive    25205     25225     25245   25265layer 5IR absorptive    25206     25226     25246   25266layer 6IR absorptive    25207     25227     25247   25267layer 7IR absorptive    25208     25228     25248   25268layer 8IR absorptive    25209     25229     25249   25268layer 9IR absorptive    25210     25230     25250   25270layer 10IR absorptive    25211     25231     25251   25171layer 11IR absorptive    25212     25232     25252   25272layer 12IR absorptive    25213     25233     25253   25273layer 13IR absorptive    25214     25234     25254   25274layer 14IR absorptive    25215     25235     25255   25275layer 15IR absorptive    25216     25236     25256   25276layer 16IR absorptive    25217     25237     25257   25277layer 17IR absorptive    25218     25238     25258   25278layer 18IR absorptive    25219     25239     25259   25279layer 19IR absorptive    25220     25240     25260   25280layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 321______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    25301     25321     25341   25361layer 1IR absorptive    25302     25322     25342   25362layer 2IR absorptive    25303     25323     25343   25363layer 3IR absorptive    25304     25324     25344   25364layer 4IR absorptive    25305     25325     25345   25365layer 5IR absorptive    25306     25326     25346   25366layer 6IR absorptive    25307     25327     25347   25367layer 7IR absorptive    25308     25328     25348   25368layer 8IR absorptive    25309     25329     25349   25369layer 9IR absorptive    25310     25330     25350   25370layer 10IR absorptive    25311     25331     25351   25371layer 11IR absorptive    25312     25332     25352   25372layer 12IR absorptive    25313     25333     25353   25373layer 13IR absorptive    25314     25334     25354   25374layer 14IR absorptive    25315     25335     25355   25375layer 15IR absorptive    25316     25336     25356   25376layer 16IR absorptive    25317     25337     25357   25377layer 17IR absorptive    25318     25338     25358   25378layer 18IR absorptive    25319     25339     25359   25379layer 19IR absorptive    25320     25340     25360   25380layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 322______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    25401     25421     25441   25461layer 1IR absorptive    25402     25422     25442   25462layer 2IR absorptive    25403     25423     25443   25463layer 3IR absorptive    25404     25424     25444   25464layer 4IR absorptive    25405     25425     25445   25465layer 5IR absorptive    25406     25426     25446   25466layer 6IR absorptive    25407     25427     25447   25467layer 7IR absorptive    25408     25428     25448   25468layer 8IR absorptive    25409     25429     25449   25469layer 9IR absorptive    25410     25430     25450   25470layer 10IR absorptive    25411     25431     25451   25471layer 11IR absorptive    25412     25432     25452   25472layer 12IR absorptive    25413     25433     25453   25473layer 13IR absorptive    25414     25434     25454   25474layer 14IR absorptive    25415     25435     25455   25475layer 15IR absorptive    25416     25436     25456   25476layer 16IR absorptive    25417     25437     25457   25477layer 17IR absorptive    25418     25438     25458   25478layer 18IR absorptive    25419     25439     25459   25479layer 19IR absorptive    25420     25440     25460   25480layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 323__________________________________________________________________________                    Substrate    Inner                                      LayerDrum    Gas used and its     temperature                           RF power                                 pressure                                      thicknessNo. flow rate (SCCM)     (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________25501    B.sub.2 H.sub.6 /He (20%)             500    250    100   0.35 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             100 ppm    NH.sub.3      10025502    B.sub.2 H.sub.6 /He (20%)             500    250    100   0.40 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             50  ppm    H.sub.2       100    NH.sub.3      30025503    B.sub.2 H.sub.6 /(20%)             500    250    100   0.35 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             100 ppm    NH.sub.3      100    Bias voltage of             +100                 V    the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 324__________________________________________________________________________                    Substrate    Inner                                      LayerDrum    Gas used and its     temperature                           RF power                                 pressure                                      thicknessNo. flow rate (SCCM)     (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________25601    B.sub.2 H.sub.6 /He (20%)             500    250    100   0.35 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             100 ppm    NH.sub.3      10025602    B.sub.2 H.sub.6 /He (20%)             500    250    100   0.40 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             50  ppm    H.sub.2       100    NH.sub.3      30025603    B.sub.2 H.sub.6 /He (20%)             500    250    100   0.35 0.5    SiH.sub.4 (against B.sub.3 H.sub.6 + NH.sub.3)             100 ppm    NH.sub.3      100    Bias voltage of             +100                 V    the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 325__________________________________________________________________________                    Substrate    Inner                                      LayerDrum    Gas used and its     temperature                           RF power                                 pressure                                      thicknessNo. flow rate (SCCM)     (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________25701    B.sub.2 H.sub.6 /He (20%)             500    250    100   0.35 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             100 ppm    NH.sub.3      10025702    B.sub.2 H.sub.6 /He (20%)             500    250    100   0.40 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             50  ppm    H.sub.2       100    NH.sub.3      30025703    B.sub.2 H.sub.6 /He (20%)             500    250    100   0.35 0.5    SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)             100 ppm    NH.sub.3      100    Bias voltage of             +100                 V    the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 326__________________________________________________________________________                     Substrate    Inner                                       LayerName of Gas used and its    temperature                            RF power                                  pressure                                       thicknesslayer flow rate (SCCM)    (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerInter- SiH.sub.4     10    250    150   0.35 0.3mediate CH.sub.4      400layerSurface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.5layer NH.sub.3      100 SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppm__________________________________________________________________________ 
    
     
                                           TABLE 327 (a)__________________________________________________________________________                      Substrate    Inner                                        LayerName of  Gas used and its    temperature                             RF power                                   pressure                                        thicknesslayer  flow rate (SCCM)    (°C.)                             (W)   (Torr)                                        (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    250   0.35 20conductive  B.sub.2 H.sub.6 (against SiH.sub.4)                100                   ppmlayer  NO            4Surface  B.sub.2 H.sub.6 /Ar (20%)                500   250    200   0.35 0.3layer  NH.sub.3      100(lower layer)  SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                100                   ppmSurface  B.sub.2 H.sub.6 /He (20%)                500   250    100   0.35 0.3layer  NH.sub.3      100(upper layer)  SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                100                   ppm__________________________________________________________________________ 
    
     
                                           TABLE 327 (b)__________________________________________________________________________                      Substrate    Inner                                        LayerName of  Gas used and its    temperature                             RF power                                   pressure                                        thicknesslayer  flow rate (SCCM)    (°C.)                             (W)   (Torr)                                        (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    250   0.35 20conductive  B.sub.2 H.sub.6 (against SiH.sub.4)                100                   ppmlayer  NO            4Surface  B.sub.2 H.sub.6 /Ar (20%)                500   250    200   0.35 0.3layer  NH.sub.3      100(lower layer)  GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                100                   ppmSurface  B.sub.2 H.sub.6 /He (20%)                500   250    100   0.35 0.3layer  NH.sub.3      100(upper layer)  GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                100                   ppm__________________________________________________________________________ 
    
     
                       TABLE 328______________________________________ Intial electri-Drum  fication  Residual       Defective                                  ImageNo.   efficiency           voltage  Ghost image   flow______________________________________(a)   ○  ⊚                    ○                          ⊚                                  ⊚(b)   ○  ⊚                    ○                          ⊚                                  ⊚______________________________________ Increase of        Break         Degree ofDrum  defective Surface  down  Abrasion                                  backgroundNo.   image     abrasion voltage                          resistance                                  fogginess______________________________________(a)   ○  ○ ⊚                          ⊚                                  ⊚(b)   ○  ○ ⊚                          ⊚                                  ⊚______________________________________ ⊚ : Excellent  ○ : Good 
    
     
                                           TABLE 329 (a)__________________________________________________________________________                      Substrate    Inner                                        LayerName of  Gas used and its    temperature                             RF power                                   pressure                                        thicknesslayer  flow rate (SCCM)    (°C.)                             (W)   (Torr)                                        (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    250   0.35 20conductive  B.sub.2 H.sub.6 (against SiH.sub.4)                100                   ppmlayer  NO            4Surface  B.sub.2 H.sub.6 /Ar (20%)                500   250    200   0.40 0.3layer  H.sub.2       100(lower layer)  NH.sub.3      100  SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                50 ppmSurface  B.sub.2 H.sub.6 /He (20%)                500   250    100   0.40 0.3layer  H.sub.2       100(upper layer)  NH.sub.3      300  SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                50 ppm__________________________________________________________________________ 
    
     
                                           TABLE 329 (b)__________________________________________________________________________                      Substrate    Inner                                        LayerName of  Gas used and its    temperture                             RF power                                   pressure                                        thicknesslayer  flow rate (SCCM)    (°C.)                             (W)   (Torr)                                        (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    250   0.35 20conductive  B.sub.2 H.sub.6 (against SiH.sub.4 )                100                   ppmlayer  NO            4Surface  B.sub.2 H.sub.6 /Ar (20%)                500   250    200   0.40 0.3layer  H.sub.2       100(lower layer)  NH.sub.3      100  GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                50 ppmSurface  B.sub.2 H.sub.6 He (20%)                500   250    200   0.40 0.3layer  H.sub.2       100(upper layer)  NH.sub.3      300  GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                50 ppm__________________________________________________________________________ 
    
     
                       TABLE 330______________________________________  Intial  electri-Drum   fication Residual        Defective                                  ImageNo.    efficiency           voltage  Ghost  image  flow______________________________________(a)    ○ ⊚                    ○                           ⊚                                  ⊚(b)    ○ ⊚                    ○                           ⊚                                  ⊚______________________________________  Increase  of                Break         Degree ofDrum   defective           Surface  down   Abrasion                                  backgroundNo.    image    abrasion voltage                           resistance                                  fogginess______________________________________(a)    ○ ○ ⊚                           ⊚                                  ⊚(b)    ○ ○ ⊚                           ⊚                                  ⊚______________________________________ ⊚ : Excellent  ○  : Good 
    
     
                       TABLE 331______________________________________  Intial  electri-Drum   fication Residual        Defective                                  ImageNo.    efficiency           voltage  Ghost  image  flow______________________________________(a)    ○ ⊚                    ○                           ⊚                                  ⊚(b)    ○ ⊚                    ○                           ⊚                                  ⊚______________________________________  Increase  of                Break         Degree ofDrum   defective           Surface  down   Abrasion                                  backgroundNo.    image    abrasion voltage                           resistance                                  fogginess______________________________________(a)    ○ ○ ⊚                           ⊚                                  ⊚(b)    ○ ○ ⊚                           ⊚                                  ⊚______________________________________ ⊚ : Excellent  ○  : Good 
    
     
                                           TABLE 332 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.3layer NH.sub.3      100(lower SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)Surface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.3layer NH.sub.3      100(upper SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)__________________________________________________________________________ 
    
     
                                           TABLE 332 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Charge SiH.sub.4     100   250    150   0.35 3injection H.sub.2       100inhibition PH.sub.3 (against SiH.sub.4)               800                  ppmlayer NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.3layer NH.sub.3      100(lower GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)Surface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.3layer NH.sub.3      100(upper GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)__________________________________________________________________________ 
    
     
                       TABLE 333______________________________________  Intial  electri-Drum   fication Residual        Defective                                  ImageNo.    efficiency           voltage  Ghost  image  flow______________________________________(a)    ⊚           ⊚                    ○                           ⊚                                  ⊚(b)    ⊚           ⊚                    ○                           ⊚                                  ⊚______________________________________  Increase  of                Break         Degree ofDrum   defective           Surface  down   Abrasion                                  backgroundNo.    image    abrasion voltage                           resistance                                  fogginess______________________________________(a)    ○ ○ ⊚                           ⊚                                  ⊚(b)    ○ ○ ⊚                           ⊚                                  ⊚______________________________________ ⊚ : Excellent  ○  : Good 
    
     
                                           TABLE 334 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.3layer NH.sub.3      100(lower SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)Surface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.3layer NH.sub.3      100(upper SiH.sub.4 (against B.sub.2 H.sub.6 +NH.sub.3)               100                  ppmlayer)__________________________________________________________________________ 
    
     
                                           TABLE 334 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.3layer NH.sub.3      100(lower GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)Surface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.3layer NH.sub.3      100(upper GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)__________________________________________________________________________ 
    
     
                       TABLE 335______________________________________  Intial  electri-Drum   fication Residual        Defective                                  ImageNo.    efficiency           voltage  Ghost  image  flow______________________________________(a)    ⊚           ⊚                    ○                           ⊚                                  ⊚(b)    ⊚           ⊚                    ○                           ⊚                                  ⊚______________________________________  Increase  of                Break         Degree ofDrum   defective           Surface  down   Abrasion                                  backgroundNo.    image    abrasion voltage                           resistance                                  fogginess______________________________________(a)    ○ ○ ⊚                           ⊚                                  ⊚(b)    ○ ○ ⊚                           ⊚                                  ⊚______________________________________ ⊚ : Excellent  ○  : Good 
    
     
                                           TABLE 336 (a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________IR    SiH.sub.4     100   250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4     50 B.sub.2 H.sub.6 (against SiH.sub.4)               1000                  ppm NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.3layer NH.sub.3      100(lower SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)Surface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.3layer NH.sub.3      100(upper SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)__________________________________________________________________________ 
    
     
                                           TABLE 336 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________IR    SiH.sub.4     100   250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4     50 PH.sub.3 (against SiH.sub.4)               800                  ppm NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.3layer NH.sub.3      100(lower GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)Surface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.3layer NH.sub.3      100(upper GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)__________________________________________________________________________ 
    
     
                       TABLE 337______________________________________ Intial electri-Drum  fication  Residual        Defective                                   ImageNo.   efficiency           voltage  Ghost  image   flow______________________________________(a)   ○  ⊚                    ○                           ⊚                                   ⊚(b)   ○  ⊚                    ○                           ⊚                                   ⊚______________________________________ Increase Sur-          Abra- of       face    Break sion  Inter-                                    Degree ofDrum  defective          abra-   down  resis-                              ference                                    backgroundNo.   image    sion    voltage                        tance fringe                                    fogginess______________________________________(a)   ○ ○                  ⊚                        ⊚                              ○                                    ⊚(b)   ○ ○                  ⊚                        ⊚                              ○                                    ⊚______________________________________ ⊚ : Excellent  ○  : Good 
    
     
                                           TABLE 338(a)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4     20    250    100   0.25 0.5layer N.sub.2       100Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.3layer NH.sub.3      100(lower SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)Surface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.3layer NH.sub.3      100(upper SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)__________________________________________________________________________ 
    
     
                                           TABLE 338 (b)__________________________________________________________________________ Gas used and its    Substrate    Inner                                       LayerName of flow rate           temperature                            RF power                                  pressure                                       thicknesslayer (SCCM)              (°C.)                            (W)   (Torr)                                       (μm)__________________________________________________________________________Contact SiH.sub.4     20    250    100   0.25 0.5layer N.sub.2       100Photo- SiH.sub.4     200   250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500   250    200   0.35 0.3layer NH.sub.3      100(lower GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)Surface B.sub.2 H.sub.6 /He (20%)               500   250    100   0.35 0.3layer NH.sub.3      100(upper GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100                  ppmlayer)__________________________________________________________________________ 
    
     
                       TABLE 339______________________________________ Intial electri-Drum  fication  Residual        Defective                                   ImageNo.   efficiency           voltage  Ghost  image   flow______________________________________(a)   ⊚           ⊚                    ○                           ⊚                                   ⊚(b)   ⊚           ⊚                    ○                           ⊚                                   ⊚______________________________________ Increase of                Break         Degree ofDrum  defective          Surface  down  Abrasion                                 backgroundNo.   image    abrasion voltage                         resistance                                 fogginess______________________________________(a)   ○ ○ ⊚                         ⊚                                 ⊚(b)   ○ ○ ⊚                         ⊚                                 ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 340 (a)__________________________________________________________________________ Gas used and its   Substrate    Inner                                      LayerName of flow rate          temperature                           RF power                                 pressure                                      thicknesslayer (SCCM)             (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________IR    SiH.sub.4     100  250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4      50 B.sub.2 H.sub.6 (against SiH.sub.4)               1000 ppm NO             10Charge SiH.sub.4     100  250    150   0.35 3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000 ppmlayer NO             10Photo- SiH.sub.4     200  250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500  250    200   0.35 0.3layer NH.sub.3      100(lower SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                100 ppmSurface B.sub.2 H.sub.6 /He (20%)               500  250    100   0.35 0.3layer NH.sub.3      100(upper SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                100 ppmlayer)__________________________________________________________________________ 
    
     
                                           TABLE 340 (b)__________________________________________________________________________ Gas used and its   Substrate    Inner                                      LayerName of flow rate          temperature                           RF power                                 pressure                                      thicknesslayer (SCCM)             (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________IR    SiH.sub.4     100  250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4      50 PH.sub.3 (against SiH.sub.4)               800 ppm NO             10Charge SiH.sub.4     100  250    150   0.35 3injection H.sub.2       100inhibition PH.sub.3 (against SiH.sub.4)               800 ppmlayer NO             10Photo- SiH.sub.4     200  250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500  250    200   0.35 0.3layer NH.sub.3      100(lower GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100 ppmlayer)Surface B.sub.2 H.sub.6 /He (20%)               500  250    100   0.35 0.3layer NH.sub.3      100(upper GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100 ppmlayer)__________________________________________________________________________ 
    
     
                                           TABLE 341__________________________________________________________________________ Intial electri-Drum  fication        Residual    Defective                          ImageNo.   efficiency        voltage             Ghost  image flow__________________________________________________________________________(a)   ⊚        ⊚             ○                    ⊚                          ⊚(b)   ⊚        ⊚             ○                    ⊚                          ⊚__________________________________________________________________________    Increase    of        Break            Degree ofDrum    defective    Surface         down             Abrasion                   Interference                          backgroundNo. image    abrasion         voltage             resistance                   fringe fogginess__________________________________________________________________________(a) ○    ○         ⊚             ⊚                   ○                          ⊚(b) ○    ○         ⊚             ⊚                   ○                          ⊚__________________________________________________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 342(a)__________________________________________________________________________ Gas used and its   Substrate    Inner                                      LayerName of flow rate          temperature                           RF power                                 pressure                                      thicknesslayer (SCCM)             (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________Contact SiH.sub.4      20  250     50   0.05 0.5layer N.sub.2        10Charge SiH.sub.4     100  250    150   0.35 3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000 ppmlayer NO             10Photo- SiH.sub.4     200  250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500  250    200   0.35 0.3layer NH.sub.3      100(lower SiH.sub.4 (against B.sub.2 H.sub.6 + NH .sub.3)                100 ppmlayer)Surface B.sub.2 H.sub.6 /He (20%)               500  250    100   0.35 0.3layer NH.sub.3      100(upper SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                100 ppmlayer)__________________________________________________________________________ 
    
     
                                           TABLE 342(b)__________________________________________________________________________ Gas used and its   Substrate    Inner                                      LayerName of flow rate          temperature                           RF power                                 pressure                                      thicknesslayer (SCCM)             (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________Contact SiH.sub.4      20  250     50   0.05 0.5layer N.sub.2        10Charge SiH.sub.4     100  250    150   0.35 3injection H.sub.2       100inhibition PH.sub.3 (against SiH.sub.4)               800 ppmlayer NO             10Photo- Si.sub.4      200  250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500  250    200   0.35 0.3layer NH.sub.3      100(lower GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100 ppmlayer)Surface B.sub.2 H.sub.6 /He (20%)               500  250    100   0.35 0.3layer NH.sub.3      100(upper GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100 ppmlayer)__________________________________________________________________________ 
    
     
                       TABLE 343______________________________________ Intial electri-Drum  fication  Residual        Defective                                   ImageNo.   efficiency           voltage  Ghost  image   flow______________________________________(a)   ⊚           ⊚                    ○                           ⊚                                   ⊚(b)   ⊚           ⊚                    ○                           ⊚                                   ⊚______________________________________ Increase of                Break         Degree ofDrum  defective          Surface  down  Abrasion                                 backgroundNo.   image    abrasion voltage                         resistance                                 fogginess______________________________________(a)   ○ ○ ⊚                         ⊚                                 ⊚(b)   ○ ○ ⊚                         ⊚                                 ⊚______________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 344(a)__________________________________________________________________________ Gas used and its   Substrate    Inner                                      LayerName of flow rate          temperature                           RF power                                 pressure                                      thicknesslayer (SCCM)             (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________Contact SiH.sub.4      20  250     50   0.05 0.5layer N.sub.2        10IR    SiH.sub.4     100  250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4      50 B.sub.2 H.sub.6 (against SiH.sub.4)               1000 ppm NO             10Charge SiH.sub.4     100  250    150   0.35 3injection H.sub.2       100inhibition B.sub.2 H.sub.6 (against SiH.sub.4)               1000 ppmlayer NO             10Photo- SiH.sub.4     200  250    300   0.40 20conductive Hz            200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500  250    200   0.35 0.3layer NH.sub.3      100(lower SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                100 ppmlayer)Surface B.sub.2 H.sub.6 /He (20%)               500  250    100   0.35 0.3layer NH.sub.3      100(upper SiH.sub.4 (against B.sub.2 H.sub.6 +NH.sub.3)                100 ppmlayer)__________________________________________________________________________ 
    
     
                                           TABLE 344(b)__________________________________________________________________________ Gas used and its   Substrate    Inner                                      LayerName of flow rate          temperature                           RF power                                 pressure                                      thicknesslayer (SCCM)             (°C.)                           (W)   (Torr)                                      (μm)__________________________________________________________________________Contact SiH.sub.4      20  250     50   0.05 0.5layer N.sub.2        10IR    SiH.sub.4     100  250    150   0.35 1absorptive H.sub.2       100layer GeH.sub.4      50 PH.sub.3 (against SiH.sub.4)               800 ppm NO             10Charge SiH.sub.4     100  250    150   0.35 3injection H.sub.2       100inhibition PH.sub.3 (against SiH.sub.4)               800 ppmlayer NO             10Photo- SiH.sub.4     200  250    300   0.40 20conductive H.sub.2       200layerSurface B.sub.2 H.sub.6 /Ar (20%)               500  250    200   0.35 0.3layer NH.sub.3      100(lower GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100 ppmlayer)Surface B.sub.2 H.sub.6 /He (20%)               500  250    100   0.35 0.3layer NH.sub.3      100(upper GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)               100 ppmlayer)__________________________________________________________________________ 
    
     
                                           TABLE 345__________________________________________________________________________ Intial electri-Drum  fication        Residual    Defective                          ImageNo.   efficiency        voltage             Ghost  image flow__________________________________________________________________________(a)   ⊚        ⊚             ○                    ⊚                          ⊚(b)   ⊚        ⊚             ○                    ⊚                          ⊚__________________________________________________________________________    Increase    of        Break            Degree ofDrum    defective    Surface         down             Abrasion                   Interference                          backgroundNo. image    abrasion         voltage             resistance                   fringe fogginess__________________________________________________________________________(a) ○    ○         ⊚             ⊚                   ○                          ⊚(b) ○    ○         ⊚             ⊚                   ○                          ⊚__________________________________________________________________________ ⊚: Excellent  ○ : Good 
    
     
                                           TABLE 346__________________________________________________________________________Gas used and its               Substrate    Inner                                 LayerDrum flow rate      temperature                      RF power                            pressure                                 thicknessNo.  (SCCM)         (°C.)                      (W)   (Torr)                                 (μm)__________________________________________________________________________27101SiH.sub.4 200  250    300   0.40 20He        200B.sub.2 H.sub.6 (against SiH.sub.4)          100 ppmNO         427102SiH.sub.4 150  250    350   0.40 20SiF.sub.4  50H.sub.2   200B.sub.2 H.sub.6 (against SiH.sub.4)          100 ppmNO         627103SiH.sub.4 200  250    300   0.40 20H.sub.2   20027104SiH.sub.4 200  250    250   0.40 20Ar        20027105SiH.sub.4 150  250    350   0.40 20SiF.sub.4  50H.sub.2   200 27106*SiH.sub.4 200  250    300   0.40 20He        200B.sub.2 H.sub.6 (against SiH.sub.4)          100 ppmNO         4 27107*SiH.sub.4 150  250    350   0.40 20SiF.sub.4  50H.sub.2   200B.sub.2 H.sub.6 (against SiH.sub.4)          100 ppmNO         6 27108*SiH.sub.4 200  250    300   0.40 20H.sub.2   200 27109*SiH.sub.4 200  250    250   0.40 20Ar        200 27110*SiH.sub.4 150  250    350   0.40 20SiF.sub.4  50H.sub.2   200__________________________________________________________________________ *surface layer followed Table 327(b) markless case: followed Table 327(a) 
    
     
                                           TABLE 347__________________________________________________________________________    Gas used and its               Substrate    Inner                                 LayerDrum    flow rate       temperature                      RF power                            pressure                                 thicknessNo. (SCCM)          (°C.)                      (W)   (Torr)                                 (μm)__________________________________________________________________________ 27201    SiH.sub.4 200   250    300   0.40 20    He        200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        427202    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        627206    SiH.sub.4 200   250    300   0.40 20    H.sub.2   20027204    SiH.sub.4 200   250    250   0.40 20    Ar        20027205    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   20027206*    SiH.sub.4 200   250    300   0.40 20    He        200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        427207*    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200    B.sub.2 H.sub.6 (against SiH.sub. 4)         100            ppm    NO        627208*    SiH.sub.4 200   250    300   0.40 20    H.sub.2   20027209*    SiH.sub.4 200   250    250   0.40 20    Ar        20027210*    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200__________________________________________________________________________ *surface layer followed Table 329(b) markless case: followed Table 329(a) 
    
     
                                           TABLE 348__________________________________________________________________________    Gas used and its               Substrate    Inner                                 LayerDrum    flow rate       temperature                      RF power                            pressure                                 thicknessNo. (SCCM)          (°C.)                      (W)   (Torr)                                 (μm)__________________________________________________________________________ 27301    SiH.sub.4 200   250    300   0.40 20    He        200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        427302    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        627303    SiH.sub.4 200   250    300   0.40 20    H.sub.2   20027304    SiH.sub.4 200   250    250   0.40 20    Ar        20027305    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   20027306*    SiH.sub.4 200   250    300   0.40 20    He        200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        427307*    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200    B.sub.2 H.sub.6 (against SiH.sub.4)         100            ppm    NO        627308*    SiH.sub.4 200   250    300   0.40 20    H.sub.2   20027309*    SiH.sub.4 200   250    250   0.40 20    Ar        20027310*    SiH.sub.4 150   250    350   0.40 20    SiF.sub.4 50    H.sub.2   200__________________________________________________________________________ *surface layer followed Table 327(b) markless case: followed Table 327(a) 
    
     
                                           TABLE 349__________________________________________________________________________    Gas used and its   Substrate    Inner                                    LayerDrum    flow rate          temperature                         RF power                               pressure                                    thicknessNo. (SCCM)             (°C.)                         (W)   (Torr)                                    (μm)__________________________________________________________________________27401    SiH.sub.4 100      250    150   0.35 3    H.sub.2   100    B.sub.2 H.sub.6 (against SiH.sub.4)         1000  ppm    GeH.sub.4 10    NO        1027402    SiH.sub.4 80       250    170   0.25 3    SiF.sub.4 20    B.sub.2 H.sub.6 (against SiH.sub.4)         1000  ppm    SnH.sub.4 5    NO        527403    SiH.sub.4 100      250    130   0.25 3    B.sub.2 H.sub.6 (against SiH.sub.4)         800   ppm    NO        4    N.sub.2   4    CH.sub.4  627404*    SiH.sub.4 100      250    150   0.35 3    H.sub.2   100    PH.sub.3 (against SiH.sub.4)         800   ppm27405*    SiH.sub.4 100      250    130   0.25 3    PH.sub.3 (against SiH.sub.4)         800   ppm    GeH.sub.4 10    NO        1027406    SiH.sub.4 100      250    150   0.35 3    H.sub.2   100    B.sub.2 H.sub.6 (against SiH.sub.4)         1000  ppm    NO**      10    NO***     10→0****__________________________________________________________________________ *surface layer followed Table 332(b) markless case: followed Table 332(a) **Substrate side 2 μm ***Surface layer side 1 μm ****Constantly changed 
    
     
                                           TABLE 350__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5*                          layer 6*                               layer 7__________________________________________________________________________Photo- 27501      27506           27511                27516                     27521                          27526                               27531conductivelayer 1Photo- 27502      27507           27512                27517                     27522                          27527                               27532conductivelayer 2Photo- 27503      27508           28513                27518                     27523                          27528                               27533conductivelayer 3Photo- 27504      27509           27514                27519                     27524                          27529                               27534conductivelayer 5Photo- 27505      27510           27515                27520                     27525                          27530                               27535conductivelayer 6__________________________________________________________________________ *surface layer followed Table 332(b) markless case: followed Table 332(a) 
    
     
                                           TABLE 351__________________________________________________________________________       Gas used and its    Substrate    Inner                                             Layer       flow rate           temperature                                  RF power                                        pressure                                             thicknessName of layer       (SCCM)              (°C.)                                  (W)   (Torr)                                             (μm)__________________________________________________________________________Surface*Lower layer       B.sub.2 H.sub.6 /Ar (20%)                     500   250    200   0.40 0.3layer A     H.sub.2       100       NH.sub.3      100       SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                     50 ppmUpper layer       B.sub.2 H.sub.6 /He (20%)                     500   250    100   0.40 0.3       H.sub.2       100       NH.sub.3      300       SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                     50 ppmSurface*Lower layer       B.sub.2 H.sub.6 /Ar (20%)                     500   250    200   0.40 0.3layer B     H.sub.2       100       NH.sub.3      100       GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                     50 ppmUpper layer       B.sub.2 H.sub.6 /He (20%)                     500   250    100   0.40 0.3       H.sub.2       100       NH.sub. 3     300       GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                     50 ppm__________________________________________________________________________ *each of the surface layers A and B is individually used in accordance with the kind of the lower layer 
    
     
                                           TABLE 352__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5*                          layer 6*                               layer 7__________________________________________________________________________Photo- 27601      27607           27613                27619                     27625                          27631                               27637conductivelayer 1Photo- 27602      27608           27614                27620                     27626                          27632                               27638conductivelayer 2Photo- 27603      27609           27615                27621                     27627                          27633                               27639conductivelayer 3Photo- 27604      27610           27616                27622                     27628                          27634                               27640conductivelayer 4Photo- 27605      27611           27617                27623                     27629                          27635                               27641conductivelayer 5Photo- 27606      27612           27618                27624                     27630                          27636                               27642conductivelayer 6__________________________________________________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 353__________________________________________________________________________       Gas used and its     Substrate    Inner                                              Layer       flow rate            temperature                                   RF power                                         pressure                                              thicknessName of layer       (SCCM)               (°C.)                                   (W)   (Torr)                                              (μm)__________________________________________________________________________Surface*Lower layer       B.sub.2 H.sub.6 /Ar (20%)                     500    250    200   0.35 0.3layer A     NH.sub.3      100       Bias voltage of                     -150                         V       the cylinder       SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                     100 ppmUpper layer       B.sub.2 H.sub.6 /He (20%)                     500    250    100   0.35 0.3       NH.sub.3      100       Bias voltage of                     +100                         V       the cylinder       SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                     100 ppmSurface*Lower layer       B.sub.2 H.sub.6 /Ar (20%)                     500    250    200   0.35 0.3layer B     NH.sub.3      100       Bias voltage of                     -150                         V       the cylinder       GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                     100 ppmUpper layer       B.sub.2 H.sub.6 /He (20%)                     500    250    100   0.35 0.3       NH.sub.3      100       Bias voltage of                     +100                         V       the cylinder       GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.                     100 ppm__________________________________________________________________________ *each of the surface layers A and B is individually used in accordance with the kind of the lower layer 
    
     
                                           TABLE 354__________________________________________________________________________ Charge      Charge           Charge                Charge                     Charge                          Charge                               Charge injection      injection           injection                injection                     injection                          injection                               injectionDrum  inhibition      inhibition           inhibition                inhibition                     inhibition                          inhibition                               inhibitionNo.   layer 1      layer 2           layer 3                layer 4                     layer 5*                          layer 6*                               layer 7__________________________________________________________________________Photo- 27701      27707           27713                27719                     27725                          27731                               27737conductivelayer 1Photo- 27702      27708           27714                27720                     27726                          27732                               27738conductivelayer 2Photo- 27703      27709           27715                27721                     27727                          27733                               27739conductivelayer 3Photo- 27704      27710           27716                27722                     27728                          27734                               27740conductivelayer 4Photo- 27705      27711           27717                27723                     27729                          27735                               27741conductivelayer 5Photo- 27706      27712           27718                27724                     27730                          27736                               27742conductivelayer 6__________________________________________________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 355______________________________________       Photo-   Photo-   Photo-Photo-      conduc-  conduc-  conduc-                                Photo-conductive  tive     tive     tive   conductiveLayer 1     Layer 2  Layer 3  Layer 5                                Layer 6______________________________________Drum  27801     27802    27803  27804  24805No.    27806*    27807*   27808*                            27809*                                   27810*______________________________________ *Surface layer followed Table 334(b) Markless case: followed Table 334(a) 
    
     
                                           TABLE 356__________________________________________________________________________Photo-    Photo-           Photo-                 Photo-                       Photo-                             Photo-conductive     conductive           conductive                 conductive                       conductive                             conductivelayer 1   layer 2           layer 3                 layer 4                       layer 5                             layer 6__________________________________________________________________________Drum    27901 27902 27903 27904 27905 27906No.  27907*      27908*            27909*                  27910*                        27911*                              27912*__________________________________________________________________________ *surface layer B was used. *markless case: surface layer A was used. 
    
     
                                           TABLE 357__________________________________________________________________________Photo-    Photo-           Photo-                 Photo-                       Photo-                             Photo-conductive     conductive           conductive                 conductive                       conductive                             conductivelayer 1   layer 2           layer 3                 layer 4                       layer 5                             layer 6__________________________________________________________________________Drum    28001 28002 28003 28004 28005 28006No.  28007*      28008*            28009*                  28010*                        28011*                              28012*__________________________________________________________________________ *surface layer B was used. markless case: surface layer A was used. 
    
     
                       TABLE 358______________________________________          Drum          No.______________________________________IR Absorptive    28101   28120*Layer 1IR Absorptive    28102   28121*Layer 2IR Absorptive    28103   28122*Layer 3IR Absorptive    28104   28123*Layer 4IR Absorptive    28105   28124*Layer 5IR Absorptive    28106   --Layer 6IR Absorptive    28107   --Layer 7IR Absorptive    28108   --Layer 8IR Absorptive    28109   --Layer 9IR Absorptive    28110   --Layer 10IR Absorptive    28111   --Layer 11IR Absorptive    28112   --Layer 12IR Absorptive    22813   --Layer 13IR Absorptive    28114   --Layer 14IR Absorptive    28115   --Layer 15IR Absorptive    28116   --Layer 17IR Absorptive    28117   28125*Layer 18IR Absorptive    28118   28126*Layer 19IR Absorptive    28119   28127*Layer 20______________________________________ *: Surface layer followed Table 336(b) Markless case: followed 336(a) 
    
     
                                           TABLE 359__________________________________________________________________________   Photo-         Photo-               Photo-                     Photo-                           Photo-Drum    conductive         conductive               conductive                     conductive                           conductiveNo.     layer 1         layer 2               layer 3                     layer 5                           layer 6__________________________________________________________________________IR absorptive   28201 28221 28241 28261 28281layer 1IR absorptive   28202 28222 28242 28262 28282layer 2IR absorptive   28203 28223 28243 28263 28283layer 3IR absorptive   28204 28224 28244 28264 28284layer 4IR absorptive   28205 28225 28245 28265 28285layer 5IR absorptive   28206 28226 28246 28266 28286layer 6IR absorptive   28207 28227 28247 28267 28287layer 7IR absorptive   28208 28228 28248 28268 28288layer 8IR absorptive   28209 28229 28249 28269 28289layer 9IR absorptive   28210 28230 28250 28270 28290layer 10IR absorptive   28211 28231 28251 28271 28291layer 11*IR absorptive   28212 28232 28252 28272 28292layer 12*IR absorptive   28213 28233 28253 28273 28293layer 13*IR absorptive   28214 28234 28254 28274 28294layer 14*IR absorptive   28215 28235 28255 28275 28295layer 15*IR absorptive   28216 28036 28256 28276 28296layer 16IR absorptive   28217 28237 28257 28277 28297layer 17*IR absorptive   28218 28238 28258 28278 28298layer 18IR absorptive   28219 28239 28259 28279 28299layer 19IR absorptive   28220 28240 28260 28280 282100layer 20__________________________________________________________________________ *: surface layer followed Table 336(b) markless case: followed Table 336(a) 
    
     
                                           TABLE 360__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-                                Photo-Drum   conductive        conductive              conductive                    conductive                          conductive                                conductiveNo.    layer 1        layer 2              layer 3                    layer 4                          layer 5                                layer 6__________________________________________________________________________IR absorptive  28301 28321 28341 28361 28381 283101layer 1IR absorptive  28302 28322 28342 28362 28382 283102layer 2IR absorptive  28303 28323 28343 28363 28383 283103layer 3IR absorptive  28304 28324 28344 28364 28384 283104layer 4IR absorptive  28305 28325 28345 28365 28385 283105layer 5IR absorptive  28306 28326 28346 28366 28386 283106layer 6IR absorptive  28307 28327 28347 28367 28387 283107layer 7IR absorptive  28308 28328 28348 28368 28388 283108layer 8IR absorptive  28309 29329 29349 29369 28389 283109layer 9IR absorptive  29310 28330 28350 28370 28390 283110layer 10IR absorptive  28311 28331 28351 28371 28391 283111layer 11*IR absorptive  28312 28332 28352 28372 28392 283112layer 12*IR absorptive  28313 28333 28353 28373 28393 283113layer 13*IR absorptive  28314 28334 28354 28374 28394 283114layer 14*IR absorptive  28315 28335 28355 28375 28395 283115layer 15*IR absorptive  28316 28336 28356 28376 28396 283116layer 16IR absorptive  28317 28337 28357 28377 28397 283117layer 17*IR absorptive  28318 28338 28358 28378 28398 283118layer 18IR absorptive  28319 28339 28359 28379 28399 283119layer 19IR absorptive  28320 28340 28360 28380 283100                                283120layer 20__________________________________________________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 361__________________________________________________________________________  Photo-        Photo-              Photo-                    Photo-                          Photo-                                Photo-Drum   conductive        conductive              conductive                    conductive                          conductive                                conductiveNo.    layer 1        layer 2              layer 3                    layer 4                          layer 5                                layer 6__________________________________________________________________________IR absorptive  28401 28421 28441 28461 28481 284101layer 1IR absorptive  28402 28422 28442 28462 28482 284102layer 2IR absorptive  28403 28423 28443 28463 28483 284103layer 3IR absorptive  28404 28424 28444 28464 28484 284104layer 4IR absorptive  28405 28425 28445 28465 28485 284105layer 5IR absorptive  28406 28426 28446 28466 28486 284106layer 6IR absorptive  28407 28427 28447 28467 28487 284107layer 7IR absorptive  28408 28428 28448 28468 28488 284108layer 8IR absorptive  28409 29429 29449 29469 28489 284109layer 9IR absorptive  29410 28430 28450 28470 28490 284110layer 10IR absorptive  28411 28431 28451 28471 28491 284111layer 11*IR absorptive  28412 28432 28452 28472 28492 284112layer 12*IR absorptive  28413 28433 28453 28473 28493 284113layer 13*IR absorptive  28414 28434 28454 28474 28494 284114layer 14*IR absorptive  28415 28435 28455 28475 28495 284115layer 15*IR absorptive  28416 28436 28456 28476 28496 284116layer 16IR absorptive  28417 28437 28457 28477 28497 284117layer 17*IR absorptive  28418 28438 28458 28478 28498 284118layer 18IR absorptive  28419 28439 28459 28479 28499 284119layer 19IR absorptive  28420 28440 28460 28480 284100                                284120layer 20__________________________________________________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 362______________________________________  Contact    Contact  Contact  Layer 2    Layer 3  Layer 4______________________________________Drum     28501        28502    28503No.       28504*       28405*   28506*______________________________________ *Surface layer followed Table 338 (b) Markless case: followed Table 338 (a) 
    
     
                       TABLE 363______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-   28601      28607*   28613   28619conductivelayer 1Photo-   28602     28608      28614* 28620conductivelayer 2Photo-    28603*   28609     28615   28621conductivelayer 3Photo-   28604     28610     28616    28622*conductivelayer 4Photo-   28605     28611      28617* 28623conductivelayer 5Photo-   28606      28612*   28618   28624conductivelayer 6______________________________________ *surface layer followed Table 338 (b) markless case: followed Table 338 (a) 
    
     
                       TABLE 364______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-   28701     28707      28713* 28719conductivelayer 1Photo-   28702      28708*   28714   28720conductivelayer 2Photo-   28703     28709     28715    28721*conductivelayer 3Photo-    28704*   28710     28716   28722conductivelayer 4Photo-   28705      28711*   28717   28723conductivelayer 5Photo-   28706     28712      28718* 28724conductivelayer 6______________________________________ 
    
     
                       TABLE 365______________________________________Drum     Contact   Contact   Contact ContactNo.      layer 1   layer 2   layer 3 layer 4______________________________________Photo-    28801*   28807     28813   28819conductivelayer 1Photo-   28802     28808      28814* 28820conductivelayer 2Photo-   28803     28809     28815    28821*conductivelayer 3Photo-   28804      28810*   28816   28822conductivelayer 4Photo-   28805     28811     28817    28823*conductivelayer 5Photo-    28806*   28812     28818   28824conductivelayer 6______________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 366______________________________________              Drum              No.______________________________________IR absorptive        28901   28921layer 1                      *IR absorptive        28902   28922layer 2                      *IR absorptive        28903   28923layer 3                      *IR absorptive        28904   28924layer 4                      *IR absorptive        28905   28925layer 5                      *IR absorptive        28906   28926layer 6                      *IR absorptive        28907   28927layer 7                      *IR absorptive        28908   28928layer 8                      *IR absorptive        28909   28929layer 9                      *IR absorptive        28910   28930layer 10                     *IR absorptive        28911   28931layer 11                     *IR absorptive        28912   28932layer 12                     *IR absorptive        28913   28933layer 13                     *IR absorptive        28914   28934layer 14                     *IR absorptive        28915   28935layer 15                     *IR absorptive        28916   28936layer 16                     *IR absorptive        28917   28937layer 17                     *IR absorptive        28918   28938layer 18                     *IR absorptive        28919   28939layer 19                     *IR absorptive        28920   28940layer 20                     *______________________________________ *: Charge injection inhibition layer and surface layer followed Table 340(b) markless case: followed Table 340(a) 
    
     
                       TABLE 367______________________________________      Photo-      Photo-    Photo-Drum       conductive  conductive                            conductiveNo.        layer 4     layer 5*  layer 7______________________________________IR absorptive      29001       29021     29041layer 1IR absorptive      29002       29022     29042layer 2IR absorptive      29003       29023     29043layer 3IR absorptive      29004       29024     29044layer 4IR absorptive      29005       29025     29045layer 5IR absorptive      29006       29026     29046layer 6IR absorptive      29007       29027     29047layer 7IR absorptive      29008       29028     29048layer 8IR absorptive      29009       29029     29049layer 9IR absorptive      29010       29030     29050layer 10IR absorptive      29011       29031     29051layer 11IR absorptive      29012       29032     29052layer 12IR absorptive      29013       29033     29053layer 13IR absorptive      29014       29034     29054layer 14IR absorptive      29015       29035     29055layer 15IR absorptive      29016       29036     29056layer 16IR absorptive      29017       29037     29057layer 17IR absorptive      29018       29038     29058layer 18IR absorptive      29019       29039     29059layer 19IR absorptive      29020       29040     29060layer 20______________________________________ *: surface layer followed Table 340(b) markless case: followed Table 340(a) 
    
     
                       TABLE 368______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    29101     29121     29141   29161layer 1IR absorptive    29102     29122     29142   29162layer 2IR absorptive    29103     29123     29143   29163layer 3IR absorptive    29104     29124     29144   29164layer 4IR absorptive    29105     29125     29145   29165layer 5IR absorptive    29106     29126     29146   29166layer 6IR absorptive    29107     29127     29147   29167layer 7IR absorptive    29108     29128     29148   29168layer 8IR absorptive    29109     29129     29149   29169layer 9IR absorptive    29110     29130     29150   29170layer 10IR absorptive    29111     29131     29151   29171layer 11IR absorptive    29112     29132     29152   29172layer 12IR absorptive    29113     29133     29153   29173layer 13IR absorptive    29114     29134     29154   29174layer 14IR absorptive    29115     29135     29155   29175layer 15IR absorptive    29116     29136     29156   29176layer 16IR absorptive    29117     29137     29157   29177layer 17IR absorptive    29118     29138     29158   29178layer 18IR absorptive    29119     29139     29159   29179layer 19IR absorptive    29120     29140     29160   29180layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 369______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    29201     29221     29241   29261layer 1IR absorptive    29202     29222     29242   29262layer 2IR absorptive    29203     29223     29243   29263layer 3IR absorptive    29204     29224     29244   29264layer 4IR absorptive    29205     29225     29245   29265layer 5IR absorptive    29206     29226     29246   29266layer 6IR absorptive    29207     29227     29247   29267layer 7IR absorptive    29208     29228     29248   29268layer 8IR absorptive    29209     29229     29249   29269layer 9IR absorptive    29210     29230     29250   29270layer 10IR absorptive    29211     29231     29251   29271layer 11IR absorptive    29212     29232     29252   29272layer 12IR absorptive    29213     29233     29253   29273layer 13IR absorptive    29214     29234     29254   29274layer 14IR absorptive    29215     29235     29255   29275layer 15IR absorptive    29216     29236     29256   29276layer 16IR absorptive    29217     29237     29257   29277layer 17IR absorptive    29218     29238     29258   29278layer 18IR absorptive    29219     29239     29259   29279layer 19IR absorptive    29220     29240     29260   29280layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 370__________________________________________________________________________Contact  Contact         Contact              Contact                   Contact                        Contact                             ContactLayer 1  Layer 2         Layer 3              Layer 4                   Layer 6                        Layer 7                             Layer 8__________________________________________________________________________Drum    29301    29302         29303              29304                   29305                        29306                             29307No.  29308*     29309*          29310*               29311*                    29312*                         29313*                              29314*__________________________________________________________________________ *Charge injection inhibition layer andsurface layer followed Table 342 (b Markless case: followed Table 342 (a) 
    
     
                                           TABLE 371__________________________________________________________________________Charge      Charge           Charge                Charge                     Charge                           Chargeinjection      injection           injection                injection                     injection                           injectionDrum inhibition      inhibition           inhibition                inhibition                     inhibition                           inhibitionNo.  layer 2      layer 3           layer 4                layer 5*                     layer 6*                           layer 7__________________________________________________________________________Contact29401 29409           29417                29425                     29433 29441layer 1Contact29402 29410           29418                29426                     29434 29442layer 2Contact29403 29411           29419                29427                     29435 29443layer 3Contact29404 29412           29420                29428                     29436 29444layer 4Contact29405 29413           29421                29429                     29437 29445layer 5Contact29406 29414           29422                29430                     29438 29446layer 6Contact29407 29415           29423                29431                     29439 29447layer 7Contact29408 29416           29424                29432                     29440 29448layer 8__________________________________________________________________________ *surface layer followed Table 342 (b) markless case: followed Table 342 (a) 
    
     
                                           TABLE 372__________________________________________________________________________Charge     Charge          Charge               Charge                    Charge                         Charge                              Chargeinjection     injection          injection               injection                    injection                         injection                              injectionDrum inhibition     inhibition          inhibition               inhibition                    inhibition                         inhibition                              inhibitionNo.  layer 1     layer 2          layer 3               layer 4                    layer 5*                         layer 6*                              layer 7__________________________________________________________________________Contact29501     29509          29517               29525                    29533                         29541                              29549layer 1Contact29502     29510          29518               29526                    29534                         29542                              29550layer 2Contact29503     29511          29519               29527                    29535                         29543                              29551layer 3Contact29504     29512          29520               29528                    29536                         29544                              29552layer 4Contact29505     29513          29521               29529                    29537                         29545                              29553layer 5Contact29506     29514          29522               29530                    29538                         29546                              29554layer 6Contact29507     29515          29523               29531                    29539                         29547                              29555layer 7Contact29508     29516          29524               29532                    29540                         29548                              29556layer 8__________________________________________________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 373__________________________________________________________________________Charge     Charge          Charge               Charge                    Charge                         Charge                              Chargeinjection     injection          injection               injection                    injection                         injection                              injectionDrum inhibition     inhibition          inhibition               inhibition                    inhibition                         inhibition                              inhibitionNo.  layer 1     layer 2          layer 3               layer 4                    layer 5*                         layer 6*                              layer 7__________________________________________________________________________Contact29601     29609          29617               29625                    29633                         29641                              29649layer 1Contact29602     29610          29618               29626                    29634                         29642                              29650layer 2Contact29603     29611          29619               29627                    29635                         29643                              29651layer 3Contact29604     29612          29620               29628                    29636                         29644                              29652layer 4Contact29605     29613          29621               29629                    29637                         29645                              29653layer 5Contact29606     29614          29622               29630                    29638                         29646                              29654layer 6Contact29607     29615          29623               29631                    29639                         29647                              29655layer 7Contact29608     29616          29624               29632                    29640                         29648                              29656layer 8__________________________________________________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 374______________________________________  Charge     Charge   Charge  injection  injection                      injection  inhibition inhibition                      inhibition  layer 4    layer 6* layer 7______________________________________Drum     29701        29702    29703No.______________________________________ *surface layer followed Table 18 (b) markless case: followed Table 18 (a) 
    
     
                       TABLE 375______________________________________    Charge    Charge    Charge  Charge    injection injection injection                                injectionDrum     inhibition              inhibition                        inhibition                                inhibitionNo.      layer 1   layer 4   layer 6*                                layer 7______________________________________Photo-   29801     29803     29805   29807conductivelayer 5Photo-   29802     29804     29806   29808conductivelayer 6______________________________________ *surface layer followed Table 18 (b) markless case: followed Table 18 (a) 
    
     
                       TABLE 376______________________________________    Charge    Charge    Charge  Charge    injection injection injection                                injectionDrum     inhibition              inhibition                        inhibition                                inhibitionNo.      layer 1   layer 4   layer 6*                                layer 7______________________________________Photo-   29901     29904     29907   29910conductivelayer 4Photo-   29902     29905     29908   29911conductivelayer 5Photo-   29903     29906     29909   29912conductivelayer 6______________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 377______________________________________    Charge    Charge    Charge  Charge    injection injection injection                                injectionDrum     inhibition              inhibition                        inhibition                                inhibitionNo.      layer 1   layer 4   layer 6*                                layer 7______________________________________Photo-   30001     30004     30007   30010conductivelayer 4Photo-   30002     30005     30008   30011conductivelayer 5Photo-   30003     30006     30009   30012conductivelayer 6______________________________________ *surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 378__________________________________________________________________________                           Substrate    Inner                                             Layer       Gas used and its    temperature                                  RF power                                        pressure                                             thicknessName of layer       flow rate (SCCM)    (°C.)                                  (W)   (Torr)                                             (μm)__________________________________________________________________________Surface*Lower layer       B.sub.2 H.sub.6 /Ar (20%)                     500   250    200   0.35 0.3layer A     NH.sub.3      100       SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                     100                        ppmUpper layer       B.sub.2 H.sub.6 /He (20%)                     500   250    100   0.35 0.3       NH.sub.3      300       SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                     100                        ppmSurface*Lower layer       B.sub.2 H.sub.6 /Ar (20%)                     500   250    200   0.35 0.3layer B     NH.sub.3      100       GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                     100                        ppmUpper layer       B.sub.2 H.sub.6 /He (20%)                     500   250    100   0.35 0.3       NH.sub.3      100       GeH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                     100                        ppm__________________________________________________________________________ *each of the surface layers A and B is individually used in accordance with the kind of the lower layer 
    
     
                       TABLE 379______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    30101     30121     30141   30161layer 1IR absorptive    30102     30122     30142   30162layer 2IR absorptive    30103     30123     30143   30163layer 3IR absorptive    30104     30124     30144   30164layer 4IR absorptive    30105     30125     30145   30165layer 5IR absorptive    30106     30126     30146   30166layer 6IR absorptive    30107     30127     30147   30167layer 7IR absorptive    30108     30128     30148   30168layer 8IR absorptive    30109     30129     30149   30169layer 9IR absorptive    30110     30130     30150   30170layer 10IR absorptive    30111     30131     30151   30171layer 11IR absorptive    30112     30132     30152   30172layer 12IR absorptive    30113     30133     30153   30173layer 13IR absorptive    30114     30134     30154   30174layer 14IR absorptive    30115     30135     30155   30175layer 15IR absorptive    30116     30136     30156   30176layer 16IR absorptive    30117     30137     30157   30177layer 17IR absorptive    30118     30138     30158   30178layer 18IR absorptive    30119     30139     30159   30179layer 19IR absorptive    30120     30140     30160   30180layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 380______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    30201     30221     30241   30261layer 1IR absorptive    30202     30222     30242   30262layer 2IR absorptive    30203     30223     30243   30263layer 3IR absorptive    30204     30224     30244   30264layer 4IR absorptive    30205     30225     30245   30265layer 5IR absorptive    30206     30226     30246   30266layer 6IR absorptive    30207     30227     30247   30267layer 7IR absorptive    30208     30228     30248   30268layer 8IR absorptive    30209     30229     30249   30269layer 9IR absorptive    30210     30230     30250   30270layer 10IR absorptive    30211     30231     30251   30271layer 11IR absorptive    30212     30232     30252   30272layer 12IR absorptive    30213     30233     30253   30273layer 13IR absorptive    30214     30234     30254   30274layer 14IR absorptive    30215     30235     30255   30275layer 15IR absorptive    30216     30236     30256   30276layer 16IR absorptive    30217     30237     30257   30277layer 17IR absorptive    30218     30238     30258   30278layer 18IR absorptive    30219     30239     30259   30279layer 19IR absorptive    30220     30240     30260   30280layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 381______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    30301     30321     30341   30361layer 1IR absorptive    30302     30322     30342   30362layer 2IR absorptive    30303     30323     30343   30363layer 3IR absorptive    30304     30324     30344   30364layer 4IR absorptive    30305     30325     30345   30365layer 5IR absorptive    30306     30326     30346   30366layer 6IR absorptive    30307     30327     30347   30367layer 7IR absorptive    30308     30328     30348   30368layer 8IR absorptive    30309     30329     30349   30369layer 9IR absorptive    30310     30330     30350   30370layer 10IR absorptive    30311     30331     30351   30371layer 11IR absorptive    30312     30332     30352   30372layer 12IR absorptive    30313     30333     30353   30373layer 13IR absorptive    30314     30334     30354   30374layer 14IR absorptive    30315     30335     30355   30375layer 15IR absorptive    30316     30336     30356   30376layer 16IR absorptive    30317     30337     30357   30377layer 17IR absorptive    30318     30338     30358   30378layer 18IR absorptive    30319     30339     30359   30379layer 19IR absorptive    30320     30340     30360   30380layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 382______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    30401     30421     30441   30461layer 1IR absorptive    30402     30422     30442   30462layer 2IR absorptive    30403     30423     30443   30463layer 3IR absorptive    30404     30424     30444   30464layer 4IR absorptive    30405     30425     30445   30465layer 5IR absorptive    30406     30426     30446   30466layer 6IR absorptive    30407     30427     30447   30467layer 7IR absorptive    30408     30428     30448   30468layer 8IR absorptive    30409     30429     30449   30469layer 9IR absorptive    30410     30430     30450   30470layer 10IR absorptive    30411     30431     30451   30471layer 11IR absorptive    30412     30432     30452   30472layer 12IR absorptive    30413     30433     30453   30473layer 13IR absorptive    30414     30434     30454   30474layer 14IR absorptive    30415     30435     30455   30475layer 15IR absorptive    30416     30436     30456   30476layer 16IR absorptive    30417     30437     30457   30477layer 17IR absorptive    30418     30438     30458   30478layer 18IR absorptive    30419     30439     30459   30479layer 19IR absorptive    30420     30440     30460   30480layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 383______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    30501     30521     30541   30561layer 1IR absorptive    30502     30522     30542   30562layer 2IR absorptive    30503     30523     30543   30563layer 3IR absorptive    30504     30524     30544   30564layer 4IR absorptive    30505     30525     30545   30565layer 5IR absorptive    30506     30526     30546   30566layer 6IR absorptive    30507     30527     30547   30567layer 7IR absorptive    30508     30528     30548   30568layer 8IR absorptive    30509     30529     30549   30569layer 9IR absorptive    30510     30530     30550   30570layer 10IR absorptive    30511     30531     30551   30571layer 11IR absorptive    30512     30532     30552   30572layer 12IR absorptive    30513     30533     30553   30573layer 13IR absorptive    30514     30534     30554   30574layer 14IR absorptive    30515     30535     30555   30575layer 15IR absorptive    30516     30536     30556   30576layer 16IR absorptive    30517     30537     30557   30577layer 17IR absorptive    30518     30538     30558   30578layer 18IR absorptive    30519     30539     30559   30579layer 19IR absorptive    30520     30540     30560   30580layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                       TABLE 384______________________________________    Photo-    Photo-    Photo-  Photo-Drum     conductive              conductive                        conductive                                conductiveNo.      layer 1   layer 4   layer 5*                                layer 7______________________________________IR absorptive    30601     30621     30641   30661layer 1IR absorptive    30602     30622     30642   30662layer 2IR absorptive    30603     30623     30643   30663layer 3IR absorptive    30604     30624     30644   30664layer 4IR absorptive    30605     30625     30645   30665layer 5IR absorptive    30606     30626     30646   30666layer 6IR absorptive    30607     30627     30647   30667layer 7IR absorptive    30608     30628     30648   30668layer 8IR absorptive    30609     30629     30649   30669layer 9IR absorptive    30610     30630     30650   30670layer 10IR absorptive    30611     30631     30651   30671layer 11IR absorptive    30612     30632     30652   30672layer 12IR absorptive    30613     30633     30653   30673layer 13IR absorptive    30614     30634     30654   30674layer 14IR absorptive    30615     30635     30655   30675layer 15IR absorptive    30616     30636     30656   30676layer 16IR absorptive    30617     30637     30657   30677layer 17IR absorptive    30618     30638     30658   30678layer 18IR absorptive    30619     30639     30659   30679layer 19IR absorptive    30620     30640     30660   30680layer 20______________________________________ *: surface layer B was used markless case: surface layer A was used 
    
     
                                           TABLE 385__________________________________________________________________________                            Substrate    Inner                                              Layer      Gas used and its      temperature                                   RF power                                         pressure                                              thicknessDrum No.   flow rate (SCCM)      (°C.)                                   (W)   (Torr)                                              (μm)__________________________________________________________________________30701    Lower layer      B.sub.2 H.sub.6 /Ar (20%)                    500     250    200   0.35 0.3      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    100  ppm      NH.sub.3      100    Upper layer      B.sub.2 H.sub.6 /He (20%)                    500     250    100   0.35 0.3      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    100  ppm      NH.sub.3      10030702    Lower layer      B.sub.2 H.sub.6 /Ar (20%)                    500     250    200   0.40 0.3      H.sub.2       100      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    50   ppm      NH.sub.3      100    Upper layer      B.sub.2 H.sub.6 /He (20%)                    500     250    100   0.40 0.3      H.sub.2       100      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    50   ppm      NH.sub.3      30030703    Lower layer      B.sub.2 H.sub.6 /Ar (20%)                    500     250    200   0.35 0.3      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    100  ppm      NH.sub.3      100      Bias voltage of                    -150 V      the cylinder    Upper layer      B.sub.2 H.sub.6 /He (20%)                    500     250    100   0.35 0.3      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    100  ppm      NH.sub.3      100      Bias voltage of                    +100 V      the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 386__________________________________________________________________________                  Substrate              Inner                                              Layer      Gas used and its                  temperature      RF power                                         pressure                                              thicknessDrum No.   flow rate (SCCM)                  (°C.)     (W)   (Torr)                                              (μm)__________________________________________________________________________30801    Lower layer      B.sub.2 H.sub.6 /Ar (20%)                    500     250    200   0.35 0.3      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    100  ppm      NH.sub.3      100    Upper layer      B.sub.2 H.sub.6 /He (20%)                    500     250    100   0.35 0.3      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    100  ppm      NH.sub.3      10030802    Lower layer      B.sub.2 H.sub.6 /Ar (20%)                    500     250    200   0.40 0.3      H.sub.2       100      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    50   ppm      NH.sub.3      100    Upper layer      B.sub.2 H.sub.6 /He (20%)                    500     250    100   0.40 0.3      H.sub.2       100      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    50   ppm      NH.sub.3      30030803    Lower layer      B.sub.2 H.sub.6 /Ar (20%)                    500     250    200   0.35 0.3      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    100  ppm      NH.sub.3      100      Bias voltage of                    -150 V      the cylinder    Upper layer      B.sub.2 H.sub.6 /He (20%)                    500     250    100   0.35 0.3      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    100  ppm      NH.sub.3      100      Bias voltage of                    +100 V      the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 387__________________________________________________________________________                            Substrate    Inner                                              Layer      Gas used and its      temperature                                   RF power                                         pressure                                              thicknessDrum No.   flow rate (SCCM)      (°C.)                                   (W)   (Torr)                                              (μm)__________________________________________________________________________30901    Lower layer      B.sub.2 H.sub.6 /Ar (20%)                    500     250    200   0.35 0.3      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    100  ppm      NH.sub.3      100    Upper layer      B.sub.2 H.sub.6 /He (20%)                    500     250    100   0.35 0.3      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    100  ppm      NH.sub.3      10030902    Lower layer      B.sub.2 H.sub.6 /Ar (20%)                    500     250    200   0.40 0.3      H.sub.2       100      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    50   ppm      NH.sub.3      100    Upper layer      B.sub.2 H.sub.6 /He (20%)                    500     250    100   0.40 0.3      H.sub.2       100      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    50   ppm      NH.sub.3      30030903    Lower layer      B.sub.2 H.sub.6 /Ar (20%)                    500     250    200   0.35 0.3      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    100  ppm      NH.sub.3      100      Bias voltage of                    -150 V      the cylinder    Upper layer      B.sub.2 H.sub.6 /He (20%) 500                         250                            100    0.35  0.3      SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                    100  ppm      NH.sub.3      100      Bias voltage of                    +100 V      the cylinder__________________________________________________________________________ 
    
     
                                           TABLE 388__________________________________________________________________________                      Substrate    Inner                                        LayerName of  Gas used and its    temperature                             RF power                                   pressure                                        thicknesslayer  flow rate (SCCM)    (°C.)                             (W)   (Torr)                                        (μm)__________________________________________________________________________Charge SiH.sub.4     100   250    150   0.35 3injection  H.sub.2       100inhibition  B.sub.2 H.sub.6 (against SiH.sub.4)                1000                   ppmlayer  NO            10Photo- SiH.sub.4     200   250    300   0.40 20conductive  H.sub.2       200layerInter- SiH.sub.4     10    250    150   0.35 0.3mediate  CH.sub.4      400layerSurface  B.sub.2 H.sub.6 /Ar (20%)                500   250    200   0.35 0.3layer  NH.sub.3      100(lower layer)  SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                100                   ppmSurface  B.sub.2 H.sub.6 /He (20%)                500   250    100   0.35 0.3layer  NH.sub.3      100(upper layer)  SiH.sub.4 (against B.sub.2 H.sub.6 + NH.sub.3)                100                   ppm__________________________________________________________________________