Abstract:
A method of preparing a semiconductor structure comprises: 
     (a) providing a first material comprising (i) a first wafer comprising silicon, (ii) at least one SiC conversion layer obtained by converting a portion of the silicon to SiC, (iii) at least one layer of non-indigenous SiC applied to the conversion layer, and (iv) at least one oxide layer applied to the non-indigenous SiC layer; 
     (b) implanting ions in a region of the non-indigenous SiC layer, thereby establishing an implant region therein which defines a first portion of the non-indigenous SiC layer and a second portion of the non-indigenous SiC layer; 
     (c) providing at least one additional material comprising (i) a second wafer comprising silicon, and (ii) an oxide layer applied to a face of the second wafer; 
     (d) bonding the oxide layer of the first material and oxide layer of the material to provide an assembly of the first material and second material; and 
     (e) separating at the implant region the second portion of the non-indigenous SiC layer from the first portion of the non-indigenous SiC layer to provide. The resultant semiconductor structure comprises a base wafer which may be a Si wafer, an insulating oxide layer which may be SiO 2  adjacent to the base wafer, and an active top layer of non-indigenous SiC. The semiconductor structure may be used to fabricate integrated electronics, pressure sensors, temperature sensors or other instrumentation which may be used in high temperature environments such as aircraft engines.

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application is a divisional application of U.S. patent application Ser. No. 09/932,001, filed Aug. 17, 2001 now U.S. Pat. No. 6,566,158. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention is directed to a method of manufacturing a semiconductor structure. More particularly, this invention is directed to a method of manufacturing a semiconductor structure to obtain a structure comprising a Si base, at least one insulating layer residing on the Si base, and a SiC layer residing on the insulating layer, in which the SiC layer is non-indigenous to the Si base. The semiconductor structure may be employed, for example, in the fabrication of high temperature instrumentation such as high temperature electronics and sensors for use in environments such as aircraft engines. 
     2. Background Information 
     The use of layers of semiconductor materials in the manufacture of sensing elements such as pressure sensors is well known to those skilled in the art. Such sensing elements are typically fabricated from one or more thin semiconductor layers residing on a thick support structure. The thin semiconductor layer or layers may be obtained by bonding the semiconductor material to a support wafer (e.g. a Si wafer), with an intermediate insulating layer residing therebetween. The semiconductor material is then thinned, typically via etching or grinding, to the desired thickness. 
     For high temperature sensor applications semiconductor materials such as silicon carbide (SiC), gallium nitride (GaN) and diamond are of particular interest, due to the wide band gap of such materials. More particularly, as disclosed, for example, in U.S. Pat. No. 5,798,293 (Harris), the cubic form 3C polytype of single crystal SiC (3C—SiC) is an advantageous semiconductor material. However, such materials are typically difficult to process, as they tend to be hard, brittle, fragile and chemically resistant. In particular, although SiC is a preferred material for use in high temperature sensor applications, SiC is very hard and chemically resistant, which makes fabrication of the sensing element difficult. For example, bonding of SiC wafers requires flat and smooth wafer surfaces, yet polishing SiC surfaces to achieve sufficient flatness and surface finish is difficult due to the hardness of SiC. Moreover, even if bonding of the SiC surface is accomplished, thinning of the SiC layer via conventional grinding or a combination of chemical and mechanical etching or polishing remains difficult. 
     Various other techniques are known for fabricating desired composite semiconductor material structures. For example, a thin film of active material (e.g. Si or SiC) may be placed on a “handle” wafer. Thereafter, insulating layers may be applied to both the active material thin layer and a separate “base” wafer. The insulating layers are then bonded or annealed to form a single structure, and the “handle” wafer is removed via etching, grinding or polishing or a combination thereof to yield a structure having a base wafer, an active top layer, and an insulating layer therebetween. 
     However, because of the disadvantages of etching, grinding and polishing techniques to remove excess Si material (such as the “handle” wafer), other semiconductor material fabrication methods have been developed. For example, in the so-called “SMART-CUT” process, described in U.S. Pat. No. 5,374,564 (Bruel), which is incorporated herein by reference, a thin semiconductor material film is prepared by bombarding a face of a semiconductor wafer material (e.g. a monocrystalline Si wafer) with hydrogen ions to a depth close to the average penetration depth of ions into the wafer, thereby defining an upper wafer portion (i.e. a thin film) and a lower wafer portion (i.e. the substrate). A stiffener constituting at least one rigid material layer is brought into contact with the planar face of the thin film portion of the wafer, and the wafer-stiffener assembly is thereafter thermally treated, thereby causing separation of the thin film from the substrate by the formation and coalescence of hydrogen filled microcracks. 
     Similarly, a method of fabricating a 3C—SiC semiconductor layer on a SiO 2  insulating layer is described by K. Vinod et al. in “Fabrication of Low Defect Density 3C—SiC on SiO 2  Structures Using Wafer Bonding Techniques,”  J. of Electronic Materials , Vol. 27, pp. L17-20 (1998) (referred to herein as Vinod et al.), which is incorporated herein by reference. The paper describes the fabrication of a 3C—SiC on SiO 2  structure in which etching is employed to expose a SiC surface on an SiO 2  layer. 
     In view of the above-described problems associated with the use of grinding, polishing and etching techniques to obtain the desired SiC active layer, it would be desirable to employ a method of manufacturing semiconductor structures having a SiC active layer residing on an insulating layer which avoids the use of such techniques. 
     It is one object of this invention to provide a method of preparing a semiconductor structure having a SiC active layer residing on an insulating layer which is prepared by using a handle wafer which is removed without etching, grinding or polishing. It is yet another object of this invention to provide high temperature pressure sensors, high temperature sensors and integrated electronics prepared from the semiconductor structure of this invention, as well as a method of preparing such sensors and integrated electronics. 
     It is one feature of this invention that a handle wafer is prepared having a Si substrate, at least one SiC active layer applied to the substrate, and an insulating layer applied to the SiC active layer. The handle wafer is bombarded with ions and the ions are implanted to a desired depth within the SiC active layer. At least one base wafer having an insulating layer is also provided, and the insulating layers of the handle and base wafers are bonded, thereby forming a single structure. Upon thermal treatment of the structure as described in the “SMART-CUT” process as described in U.S. Pat. No. 5,374,564 (Bruel), the Si substrate and a portion of each SiC layer of the handle wafer is removed, yielding at least one semiconductor structure having a base wafer, an oxide insulating layer residing on the base wafer, and a top SiC active layer residing on the insulating layer. 
     The method of this invention advantageously may employ thicker wafers which tend to remain flat and facilitate bonding thereto. In addition, the method of this invention advantageously permits the manufacture of large diameter (say 4 inches in diameter) SiC on insulator (SiCOI) having excellent crystal properties which are obtained without using etching. Other objects, features and advantages of this invention will be apparent to those skilled in the art in view of the detailed description of the invention provided below. 
     SUMMARY OF THE INVENTION 
     The method of this invention comprises: 
     providing a first material comprising (i) a first (i.e. handle) wafer comprising silicon, (ii) at least one SiC conversion layer obtained by converting a portion of the silicon from the handle wafer to SiC, (iii) at least one layer of non-indigenous SiC applied to the conversion layer, and (iv) at least one oxide layer applied to the non-indigenous SiC layer, wherein a region of the non-indigenous SiC layer has ions implanted therein, thereby establishing an implant region therein which defines a first portion of the non-indigenous SiC layer and a second portion of the non-indigenous SiC layer; 
     providing at least one additional material comprising (i) a second (i.e. base wafer) comprising silicon, and (ii) an oxide layer applied to a face of the base wafer; 
     bonding the oxide layer of the first material and oxide layer of the additional material to provide an assembly of the first material and additional material; and 
     separating at the implant region the second portion of the non-indigenous SiC layer from the first portion of the non-indigenous SiC layer, thereby providing at least one semiconductor structure having a silicon base, at least one oxide insulating layer thereon, and a non-indigenous SiC active top layer residing on the oxide insulating layer. The semiconductor structure obtained from the method of this invention may be used to fabricate integrated electronics, temperature sensors, pressure sensors or other instrumentation which may be used in high temperature environments such as aircraft engines. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIGS. 1A-1G depict cross-sectional views of one embodiment of the method of this invention. 
     FIGS. 2A-2G depict cross-sectional views of another specific embodiment of the method of this invention, in which two semiconductor structures of this invention are simultaneously prepared. 
     FIGS. 3A-3K depict cross-sectional views of a specific embodiment of this invention, in which a pressure sensor is fabricated. 
     FIGS. 4A-4E depict cross-sectional views of another specific embodiment of this invention, in which a pressure sensor is fabricated. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     The present invention combines the desirable aspects of the use of a SiC film on a Si “handle” wafer, as described in Vinod et al., and the SMART-CUT process as described in U.S. Pat. No. 5,374,564 (Bruel) to obtain a semiconductor structure having a Si base layer, an oxide insulating layer thereon, and a SiC top layer residing on the oxide insulating layer. This structure is obtained while avoiding the use of etching, grinding or polishing to remove the Si handle wafer from the SiC film by employing the ion implantation technique of the SMART-CUT process to achieve removal of the Si handle wafer. The present invention preserves the cost advantage of the SMART-CUT process and extends it to more easily and reliably obtain an SiC active layer residing on an oxide insulating layer: i.e. a SiCOI substrate in which a monocrystalline SiC film resides on at least one insulating layer which insulates the SiC film from the underlying base layer or substrate. 
     The invention is described in greater detail herein relative to non-limiting embodiments of the invention and with reference to the drawings. FIGS. 1A-G show cross sectional views of the various method steps employed in one embodiment of the invention to prepare the desired semiconductor structure. In FIG. 1A, a first or “handle” wafer  2  which is a Si wafer having a thickness of about 0.3-1.2 mm, say about 1 mm is shown. FIG. 1B depicts the handle wafer  2  having a SiC layer  4  applied to a face of the handle wafer  2 . The SiC layer  4  has a total thickness of about 0.5-1.5 μm, say 1 μm. SiC layer  4  comprises an initial conversion layer  3  and an epitaxial layer  5  residing thereon. The conversion layer  3  is a 3C—SiC layer having a thickness of about 100 Angstroms which is indigenous to the handle wafer  2  and is obtained by converting a portion of Si wafer 2 to 3C—SiC as described, for example, by Wu et al. in “The Microstructure and Surface Morphology of Thin 3C—SiC Films Grown on (100) Si Substrates Using an APCVD-Based Carbonization Process,”  Materials Science Forum , Vols. 353-356, pp. 167-70 (2001), which is incorporated herein by reference. This is followed by application of an epitaxial layer  5  of additional SiC (which is not indigenous to the handle wafer) upon the converted SiC layer  3  using a chemical vapor deposition process such as atmospheric pressure chemical vapor deposition (APCVD) as described, for example, by Fleishman et al. in “Epitaxial Growth of 3C—SiC Films on 4-inch Diameter (100) Silicon Wafers by APCVD,” presented at the Silicon Carbide and Related Materials 1995 Conference, Kyoto, Japan, pp. 197-200. Epitaxially grown SiC layer  5  is advantageous in that it provides a virtually defect-free SiC layer for use in the semiconductor structure of this invention, because defects in the SiC crystals remain in the portion of the SiC layer  4  which remains integral to the discarded handle wafer, as further described herein. 
     FIG. 1C depicts an oxide layer  6  applied to SiC layer  4 . The oxide layer  6  is preferably a SiO 2  layer which has been obtained by techniques known to those skilled in the art, including thermal oxidation or chemical vapor deposition (CVD), preferably CVD, as will be well understood by those skilled in the art. Plasma enhanced chemical vapor deposition (PECVD) is particularly preferred to obtain oxide layer  6 . The oxide layer  6  typically has a thickness of about 1000 Angstroms. 
     In FIG. 1D, the substrate of FIG. 1C has been subjected to ion bombardment, thereby implanting ions in an implant region  8  (shown in dashed lines) which is located in the epitaxial SiC layer  5 . Implantation must be performed such that above the implant region  8  is at least a portion  10  of the epitaxial SiC layer  5  and the oxide layer  6  adjacent to portion  10 , and below the implant region  8  is the conversion SiC layer  3 , and the handle wafer  2  adjacent thereto. The ions employed may be hydrogen gas ions and possibly other ions alone or in combination such as boron, carbon, phosphorus, nitrogen, arsenic or fluorine ions, most preferably hydrogen gas ions. Ion implantation may be accomplished via techniques and equipment well known to those skilled in the art, such as the method described in U.S. Pat. No. 5,374,564 (Bruel) at col. 5, line 8-col. 6 line 10, which is incorporated herein by reference. The temperature of the substrate of FIG. 1C during implantation is preferably kept below the temperature at which gas (which is produced by the implanted ions) can escape via diffusion from the substrate of FIG. 1C or its component layers. Ion implantation causes a concentrated layer of ions to form and reside in the implant region  8  at a depth close to the average penetration depth of the ions into the SiC layer  4 . 
     The oxide layer  6  is typically damaged during the ion implantation process, and accordingly oxide layer  6  is stripped from the epitaxial SiC layer  5  after ion implantation using wet etch in buffered oxide etch (BOE) or dry etch in reactive ion etch (RIE). The epitaxial SiC layer  5  is then cleaned with SO 5 /HF/Chelate, and PECVD is again employed to provide the ion-implanted epitaxial SiC layer  5  with a new oxide layer  9 . The oxide layer  9  balances film stresses and wafer distortion, such that the original wafer flatness is retained. Subsequent polishing and cleaning of the oxide layer  9  may be achieved via the use of chemical-mechanical polishing (CMP), which is a process of using a fine polishing disc with wet chemical enhancement to achieve a fine finish on semiconductor materials (for example, silicon, oxides and nitrides), as will be well understood by those skilled in the art. The desired finish is a flatness of less than 1 micron and a surface of less than 5 Angstroms RMS. 
     FIG. 1E depicts the ion implanted material of FIG. 1D with new oxide layer  9  (labeled I) in proximity to a second material (labeled II) having a base wafer  14  and an oxide layer  16  applied thereto. The base wafer  14  comprises silicon, and in a preferred embodiment is a Si wafer having a thickness of about 100-5000 μm, preferably 300-1000 μm, most preferably about 300-500 μm. The oxide layer  16  is preferably a SiO 2  layer obtained as previously described with respect to oxide layers  6  and  9 . Oxide layer  16  has a thickness of about 1-25 μm, say about 10 μm, and may be cleaned and polished using CMP as previously described with respect to oxide layer  9 . Material I is shown inverted as contemplated in the method of this invention for adjoining to material II. 
     The oxide layers  9  and  16  of the materials I and II, respectively, are bonded as depicted in FIG. 1F to provide a single assembly. The bonded interface  15  shows the interface between the bonded oxide layers  9  and  16 . The oxide layers are preferably bonded by chemically treating each oxide layer  9  and  16  by chemical activation of these surfaces followed by mechanical adjoining. As will be well understood by these skilled in the art, chemical activation is typically achieved by forming a hydrophilic surface which attaches an OH radical to the SiO 2  molecules residing in the oxide layers. The OH radicals on each oxide surface are attracted to each other, which aids the bonding process. The presence of moisture may also be desirable. The OH radicals are typically provided by cleaning the oxide surfaces with one or more of the following commercially available chemical surface cleaning formulations: SC-1 (hydrogen peroxide, ammonium hydroxide and deionzed water); SC-2 (hydrochloric acid, hydrogen peroxide and deionzed water); “Piranha” (sulfuric acid and hydrogen peroxide); and “Chelate” (a 1:3 blend of hydrogen peroxide and ammonium hydroxide). SC-1, SC-2 and Piranha are described, for example, in S. Wolf and R. Tauber,  Silicon Processing For The VLSI Era, Vol.  1:  Process Technology  (2d ed. 1986), pp. 128-29. 
     After materials I and II have been joined at the interface  15  of oxide layers  9  and  16  to form a single assembly (as depicted in FIG.  1 F), the assembly is separated in the vicinity of the ion implant region  8 . This separation is preferably achieved by first heating the assembly to a temperature of about 800-900° C., preferably about 850° C. for up to about one hour, preferably about 0.5 hours. During this first heating step, coalescence of the implanted ion species (e.g. hydrogen) forms microcracks cleaving the assembly in the implant region  8 . The heating of the assembly must be at a temperature above that at which the ion bombardment was carried out. After cleavage or separation as described above, the resulting semiconductor material has the structure depicted in FIG.  1 G: i.e. a base Si wafer  14  having thereon at least one oxide insulating layer (oxide layers  16  and  9  in FIG. 1G) and an active non-indigenous epitaxial SiC top layer  10  which is electrically insulated from the base wafer  14  by the at least one oxide insulating layer (shown as the combination of oxide layers  9  and  16  in FIG.  1 G). SiC layer  10  is composed only of non-indigenous epitaxially grown SiC obtained as previously described. A subsequent heating of the resulting semiconductor structure depicted in FIG. 1G is then employed in which it is heated to a temperature of 1100-1200° C., preferably about 1150° C. for about 0.5 hours. The SiC layer  10  may then be polished as necessary using techniques well known to those skilled in the art. An additional epitaxial SiC layer (not shown) may also optionally be grown upon SiC layer  10 . 
     FIGS. 2A-2G show cross-sectional views of various method steps employed in another embodiment of this invention to prepare two semiconductor structures using a single handle wafer and two base wafers. FIG. 2A depicts a structure having a first or “handle” wafer  202  which is a Si wafer having a thickness of about 0.3-1.2 mm, say about 1 mm. As shown in FIG. 2B, handle wafer  202  has a first SiC layer  104  applied to a face of the handle wafer  202 , and a second SiC layer  204  applied to the opposite face of handle wafer  202 . First SiC layer  104  comprises an initial conversion layer  103  and a non-indigenous epitaxial layer  105  residing thereon. Second SiC layer  204  comprises an initial conversion layer  203  and a non-indigenous epitaxial layer  205  residing thereon. Each SiC layer  104  and  204  is prepared as previously described with respect to FIGS. 1A and 1B. 
     FIG. 2C depicts an oxide layer  106  applied to non-indigenous SiC layer  105 , and an oxide layer  206  applied to non-indigenous SiC layer  205 . The oxide layers  106  and  206  are preferably each a SiO 2  layer which has been obtained as previously described with respect to FIG.  1 C. 
     In FIG. 2D, the substrate of FIG. 2C has been subjected to ion bombardment, thereby implanting ions in implant region  108  and  208  (shown in dashed lines) which are located in the epitaxial layers  105  and  205 , respectively. Above the implant region  108  is at least a portion  110  of the epitaxial SiC layer  105 , and below the implant region  208  is at least a portion  210  of the epitaxial SiC layer  205 . Ion implantation and subsequent treatment is as described above with respect to FIG.  1 D. As previously described, oxide layers  106  and  206  are damaged during ion bombardment, and are replaced by oxide layers  107  and  207 , which are obtained as previously described for oxide layers  106  and  206 . 
     FIG. 2E depicts the ion implanted material of FIG. 2D (labeled VI) in proximity to a second material (labeled III) having a base wafer  115  and an oxide layer  117  applied thereto and a third material (labeled IV) having a base wafer  215  and an oxide layer  217  applied thereto. The base wafers  115  and  215  each comprises silicon, and in a preferred embodiment each is a Si wafer having a thickness of about 100-5000 μm, preferably 300-1000 μm, most preferably about 300-500 μm. The oxide layers  117  and  217  are each preferably a SiO 2  layer obtained as previously described with respect to oxide layers  105  and  205 . Oxide layers  117  and  217  each have a thickness of about 1-25 μm, say about 10 μm. Material III is shown inverted as contemplated in the method of this invention for adjoining to material V, and material IV is also shown in proximate relation to material V prior to adjoining thereto. 
     The oxide layers  107  and  117  of the materials V and III, respectively, and the oxide layers  207  and  217  of the materials V and IV, respectively, are bonded as depicted in FIG. 2F to provide a single assembly. Bonding is accomplished as previously described with respect to FIGS. 1E and 1F. Inferface  125  is the bonded interface of oxide layers  107  and  117 , and interface  225  is the bonded interface of oxide layers  207  and  217 , as shown in FIG.  2 E. 
     After materials III, V and IV have been joined to form a single assembly (as depicted in FIG.  2 F), the assembly is separated in the vicinity of the ion implant regions  108  and  208 . This separation is achieved as previously described with respect to FIGS. 1F and 1G. After cleavage or separation as described above, the resulting two semiconductor structures are as depicted in FIG.  2 G: i.e. the first semiconductor structure has a base Si wafer  115  having thereon at least one oxide insulating layer (oxide layers  117  and  107  in FIG. 2G) and an active non-indigenous SiC top layer  110  which is electrically insulated from the base wafer  115  by the at least one oxide insulating layer (shown as the combination of oxide layers  117  and  107  in FIG.  2 G), and the second semiconductor structure has a base Si wafer  215  having thereon at least one oxide insulating layer (oxide layers  217  and  207  in FIG. 2G) and an active non-indigenous SiC top layer  210  which is electrically insulated from the base wafer  215  by the at least one oxide insulating layer (shown as the combination of oxide layers  207  and  217  in FIG.  2 G). A subsequent heating of the resulting semiconductor structures depicted in FIG. 2G is then employed in which the resulting semiconductor structures are heated to a temperature of 1100-1200° C., preferably about 1150° C. for about 0.5 hours. The SiC layers  110  and  210  of each material may then be polished using techniques well known to those skilled in the art. An additional epitaxial layer (not shown) may also optionally be grown upon SiC layers  110  and  210 , respectively. 
     The semiconductor structure obtained from the method of this invention is particularly useful in fabricating electronic parts and instrumentation which must be used in hostile environments. In one embodiment, the semiconductor structure may be employed in connection with the fabrication of a pressure sensor useful in high temperature (e.g. 400-600° C.) applications, such as for the measurement of pressure at the exhaust portion of a jet engine. Such an embodiment is described below with reference to FIGS. 3A-3K. 
     FIGS. 3A-3K show cross sectional views of the various method steps employed in one embodiment of this invention to prepare a pressure sensor of this invention. In FIG. 3A, a first or “handle” wafer  302  which is preferably a Si wafer having a thickness of about 0.3-1.2 mm, preferably about 1 mm. The handle wafer  302  has a SiC layer  304  applied to a face of the handle wafer  302 . The SiC layer  304  comprises a conversion layer  303  and a non-indigenous SiC layer  305 . Oxide layer  306  (not shown) is initially applied to non-indigenous SiC layer  305 . 
     As shown in FIG. 3A, the substrate has been subjected to ion bombardment, thereby implanting ions in an implant region  308  (shown in dashed lines) which is located in the non-indigenous SiC layer  305 . Above the implant region  308  is at least a portion  310  of the non-indigenous SiC layer  305  and the initial oxide layer  306  (not shown) adjacent to the non-indigenous SiC layer  305 . The initial oxide layer  306  is damaged during ion implantation, and has been replaced by oxide layer  309  as shown in FIG.  3 A. Preparation of the material depicted in FIG. 3A is accomplished as previously described with respect to FIGS. 1A-1D. The material depicted in FIG. 3A is labeled as material VI. 
     FIG. 3B depicts a Si wafer  314  having a thickness of about up to 500 μm, preferably about 300-325 μm, say about 318 μm. Si wafer  314  has a lower face  321  and an upper face  319 . A pressure sensor diaphragm  322  has been etched, cut or otherwise provided in the Si wafer  314 , using techniques which are well known to those skilled in the art. FIG. 3C depicts the Si wafer  314  having the pressure sensor diaphragm cavity  322  after wafer  314  has been bonded at face  321  to another Si wafer  324  having a thickness of up to about 1000 μm, preferably 300-1000 μm, most preferably about 800 μm. Si wafer  324  has a passageway  325  therethrough which operatively interfaces pressure sensor diaphragm cavity  322 , thereby providing a pathway for a fluid medium (e.g. aircraft engine exhaust gas) to contact pressure sensor diaphragm cavity  322  to enable measurement of the pressure of the gaseous medium. In FIG. 3C, Si wafer  314  also has an oxide layer  316  applied to Si wafer  314 . Oxide layer  316  may be applied by a chemical vapor deposition process such as PECVD as previously described, or may preferably be obtained by fusing wafers  314  and  324  in an oxidizing atmosphere, thereby causing formation of oxide layer  316  which is a thermal oxide layer on the upper face  319  of wafer  314 . The oxide layer  316  has a thickness of about 1-20 μm, say about 1 μm. The assembly of wafer  314  having oxide layer  316  on face  319  thereof and wafer  324  bonded to wafer  314  at face  321  thereof is labeled as material VII in FIG.  3 C. 
     FIG. 3D depicts the ion implanted material of FIG. 3A (labeled as material VI) bonded to the second material of FIG. 3C (labeled as material VII). Material VI is shown inverted as contemplated in the method of this invention for adjoining to material VII. The oxide layers  309  and  316  of materials VI and VII, respectively, are bonded as depicted in FIG. 3D to provide a single assembly. The bonded interface  315  shows the interface between the bonded oxide layers  309  and  316 . The oxide layers are bonded using techniques as previously described with respect to bonded materials I and II in FIG.  1 F. 
     After materials VI and VII have been joined at the interface  315  of oxide layers  309  and  316  to form a single assembly (as depicted in FIG.  3 D), separation at the vicinity of the ion implantation region  308  is achieved as previously described with respect to FIGS. 1F and 1G. After cleavage or separation as described above, a pressure sensor precursor is obtained having the structure depicted in FIG.  3 E: i.e. a base Si wafer  324  fusion bonded to Si wafer  314 , with Si wafer  314  having thereon at least one oxide insulating layer (shown in FIG. 3E as the single layer  326  which is the combination of oxide layers  316  and  309  in FIG. 3D) and an active non-indigenous SiC top layer  310  which is electrically insulated from the base wafers  314  and  324  by the oxide insulating layer  326 . A subsequent heating of the resulting semiconductor material depicted in FIG. 3E is then employed in which the resulting semiconductor material is heated to a temperature of 1100-1200° C., preferably about 1150° C. for about 0.5 hours. SiC layer  310  may optionally be made thicker using an appropriate chemical vapor deposition technique such as APCVD as previously described, which provides additional SiC (which is not indigenous to the handle wafer). SiC layer  310  may be polished using techniques well known to those skilled in the art. 
     An oxide or metal film, photolithographic emulsion, mask and developer are then employed to provide a protective layer or layers (not shown) in a pattern emulating the pattern desired in SiC layer  310 . The photolithographic emulsion is used to pattern the oxide or metal film which in turn is used to protect selected areas of the SiC during etching. The unprotected portion of SiC layer  310  is then selectively removed, as will be well understood by those skilled in the art. As shown in FIG. 3F, after portions of SiC layer  310  have been selectively removed, preferably using RIE, underlying portions of oxide layer  326  are exposed. Upon removal of the remaining protective layer (not shown) a passivation layer  330 , preferably Si-nitride, is then applied over the exposed portions of oxide layer  326  and the remaining portions of SiC layer  310 , as shown in FIG.  3 G. As shown in FIG. 3H, opening  332  is provided for access to Si wafer  314 , and opening  334  is provided for access to a remaining portion of SiC layer  310 . Metal contact  336  is provided through opening  332  to contact Si wafer  314 , and metal contact  338  is provided through opening  334  to contact SiC layer  310 , as shown in FIG. 3I, thereby providing the necessary electronic connections to the semiconductor material. 
     To facilitate its intended use, the pressure sensor as shown in FIG. 3I is preferably adjoined or affixed to a base portion or pedestal  340  shown in FIG. 3J having a conduit  342  therethrough, as described, for example in U.S. Pat. No. 5,515,732, incorporated herein by reference. In a preferred embodiment, base portion  340  is anodically bonded to the lower face  341  of Si wafer  324  as shown. Conduit  342  is operatively associated and aligned with passageway  325  as shown in FIG. 3J to permit passage of the gaseous medium (e.g. aircraft engine exhaust gas) through conduit  342  and passageway  325  to contact pressure sensor diaphragm cavity  322  to enable measurement of the pressure of the gaseous medium. The base portion or pedestal  340  is a fabricated from a material capable of withstanding high temperatures (i.e. 300-1000° C.), such as a ceramic or SiC material. In one preferred embodiment of this invention, the base portion or pedestal is preferably fabricated from PYREX glass. In a particularly preferred embodiment, the exposed or non-bonded end  343  of base portion  340  may be metallized to facilitate further bonding or mounting (not shown). As depicted in FIG. 3K, this may be accomplished by providing one or more metal layers  344  on the exposed or non-bonded end  343  of base portion  340 . This metal layer is preferably a tri-metal layer, as described, for example, in U.S. Pat. No. 5,515,732. 
     In another embodiment, as depicted in FIG. 4A, a first material may be prepared as described above with respect to FIG.  3 A. FIG. 4A depicts a first or “handle” wafer  402  having a SiC layer  404  applied to a face of the handle wafer  402 . The SiC layer  404  comprises a conversion layer  403  and a non-indigenous SiC layer  405 . Oxide layer  406  (not shown) is initially applied to non-indigenous SiC layer  405 . Implant region  408  located in layer  405  is also shown. Oxide layer  406  is damaged during ion implantation, and has been replaced by oxide layer  409 . FIG. 4B depicts a Si wafer  414  having an upper surface  419  and a pressure sensor diaphragm  422  etched, cut or otherwise provided in Si wafer  414 , as previously described with respect to FIG.  3 B. FIG. 4C depicts an oxide layer  416  applied to the upper surface  419  of Si wafer  414 . Oxide layer  416  may be applied as previously described, and has a thickness of about 1-20 μm, say about 1 μm. As shown in FIG. 4D, the ion implanted material of FIG. 4A (labeled as material VIII) is bonded to the second material of FIG. 4C (labeled as material IX) by bonding oxide layers  409  and  416  to provide a single assembly. The oxide layers  409  and  416  are bonded using techniques as previously described. After materials VIII and IX have been joined at the interface of oxide layers  409  and  416  to form a single assembly (as depicted in FIG.  4 D), another Si wafer  424  having a thickness of about 100-1000 μm, preferably 300-1000 μm, most preferably about 300-500 μm is fusion bonded to face  421  of joined materials VIII and IX, as depicted in FIG.  4 E. As described with respect to FIG. 3C, Si wafer  414  has a passageway  425  therethrough which operatively interfaces pressure sensor diaphragm cavity  422 , thereby providing a pathway for a fluid medium (e.g. aircraft engine exhaust gas) to contact pressure sensor diaphragm cavity  422  to enable measurement of the pressure of the gaseous medium. The assembly as depicted in FIG. 4E may then be separated at the vicinity of the ion implantation region  408  and further processed as described above with respect to FIGS. 3E-3K to obtain the pressure sensor of this invention. 
     Although this invention has been illustrated by reference to specific embodiments, it will be apparent to those skilled in the art that various changes and modifications may be made which clearly fall within the scope of this invention.