Abstract:
A device transfer method includes the steps of: covering a plurality of devices, which have been formed on a substrate, with a resin layer; forming electrodes in the resin layer in such a manner that the electrodes are connected to the devices; cutting the resin layer, to obtain resin buried devices each containing at least one of the devices; and peeling the resin buried devices from the substrate and transferring them to a device transfer body. This device transfer method is advantageous in easily, smoothly separating devices from each other, and facilitating handling of the devices in a transfer step and ensuring good electric connection between the devices and external wiring, even if the devices are fine devices.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS  
       [0001]     The present application is a continuation of U.S. patent application Ser. No. 10/950,024 filed on Sep. 23, 2004, which is a continuation of U.S. patent application Ser. No. 10/062,776 filed on Jan. 30, 2002, now issued as U.S. Pat. No. 6,830,946, and which claims priority to Japanese Patent Application No. P2001-025114 filed on Feb. 1, 2001, the above-referenced disclosures of which are herein incorporated by reference. 
     
    
     BACKGROUND OF THE INVENTION  
       [0002]     The present invention relates to a device transfer method of transferring light emitting devices such as light emitting diodes, which have been formed on a substrate, for example, a sapphire substrate, to a device transfer body such as a display panel, and to a panel on which the transferred devices are arrayed.  
         [0003]     A known method of producing an LED (Light Emitting Diode) display using LEDs includes the steps of cutting an LED wafer, which is obtained by stacking semiconductor layers on a device formation substrate, into chips by a diamond blade or the like, and transferring the LED chips to a display panel or the like with a pitch larger than an array pitch of the LED chips on the device formation substrate.  
         [0004]     The above-described cutting method, however, has problems. For example, blue light emitting diodes are produced by stacking gallium nitride based semiconductor layers on a sapphire substrate as a device formation substrate. In this case, sapphire used as the material of the substrate is as very hard, about 9 in Mohs&#39; hardness. As a result, if the sapphire substrate is full cut into chips by a dicer such as a diamond blade, problems such as cracking and/or chipping tend to occur in the cut planes of the sapphire substrate which prevent the sapphire substrate from being smoothly cut into chips of desired shapes and sizes, the dicer itself may also be broken, and that since sapphire has no cleavage characteristic, it is difficult to cut the sapphire substrate into chips by forming scribing lines on the sapphire substrate and forcibly cutting the sapphire substrate along the scribing lines by an external force.  
         [0005]     To solve the above problems, a method of cutting a sapphire substrate has been disclosed, for example, in Japanese Patent Laid-open No. Hei 5-315646. According to this method, as shown in  FIG. 12 , a gallium nitride semiconductor layer  61  formed on a sapphire substrate  60  is cut by a dicer to form grooves  62  deeper than a thickness of the gallium nitride semiconductor layer  61 . The sapphire substrate  60  is thinned by polishing a back surface of the sapphire substrate  60 . Scribing lines  63  are formed on the sapphire substrate  60  via the grooves  62  by a scriber. The sapphire substrate  60  is then forcibly cut into chips by an external force. This document describes how the sapphire substrate can be smoothly cut into chips without occurrence of cracking and/or chipping in the cut planes of the sapphire substrate  50 . However, such a cutting method, requires several steps including the labor intensive step of polishing the sapphire substrate  60 . In other words, the above method of cutting a sapphire substrate  60  is expensive and time consuming.  
         [0006]     If a larger number of LED devices are obtained from one device formation substrate, the cost of one LED device can be reduced and the cost of a display unit using such LED devices can be also reduced. In the method disclosed in the above document, Japanese Patent Laid-open No. Hei 5-315646, LED devices each having a size of 350 μm per side are obtained from the sapphire substrate having a diameter of two inches. If LED devices each having a size of several tens μm per side are obtained from the sapphire substrate having a diameter of two inches and a display unit is produced by transferring the LED devices on a display panel, it is possible to reduce the cost of a display unit.  
         [0007]     However, if the size of each LED device becomes as small as several tens of μm per side, it becomes difficult to handle the LED device in the transfer step. Further, since an electrode of each device to be connected to a wiring layer of a base body of a display panel becomes small, the connection work becomes difficult and also a connection failure may often occur.  
       SUMMARY OF THE INVENTION  
       [0008]     The present invention provides in an embodiment a device transfer method capable of easily, smoothly separating devices from each other, and facilitating handling of devices in a transfer step and ensuring good electrical connection between the devices and external wiring, although the devices are fine devices, and to provide a panel on which the transferred devices are arrayed.  
         [0009]     According to a first embodiment of the present invention, a device transfer method is provided, the method includes covering a plurality of devices, formed on a substrate, with a layer of resin; the resin layer is then cut, to obtain resin buried devices each of which contains at least one of the devices. The resin buried devices are then peeled from the substrate and transferred to a device transfer body.  
         [0010]     With this configuration, the resin buried device being handled has a size larger than the device itself. The larger size of the resin buried device facilitates the handling of the devices in the transfer step. Since respective resin buried devices are obtained by cutting only the resin layer without the need of cutting the substrate, it is possible to easily obtain the resin buried devices because the resin layer can be easily, smoothly cut. Further, the substrate, which is not cut, can be reused.  
         [0011]     According to a second embodiment of the present invention, a device transfer method is provided which includes a step of covering a plurality of devices, which have been formed on a substrate, with a resin layer. Electrodes are formed in the resin layer in a manner such that the electrodes are connected to the devices. The method further includes cutting the resin layer to obtain resin buried devices, each containing at least one of the devices. The resin buried devices are then peeled from the substrate and transferred to a device transfer body.  
         [0012]     With this configuration, the resin buried device being handled has a size larger than that of the device itself. The larger size of the resin buried device facilitates the handling of the devices in the transfer step. Since the electrode is formed in the resin layer in such a manner as to be connected to the device, it is possible to easily form the electrode, and to prevent connection failures between the electrode and an external electrode by increasing the area of the electrode. Since respective resin buried devices are obtained by cutting only the resin layer without the need of cutting the substrate, it is possible to easily obtain the resin buried devices because the resin layer can be easily, smoothly cut. Further, the substrate, which is not cut, can be reused.  
         [0013]     According to a third embodiment of the present invention, a device transfer method is provided which includes the step of covering a plurality of devices, which have been formed on a device formation substrate, with a first resin layer. The method further includes collectively peeling the devices, together with the first resin layer, from the device formation substrate, and transferring them to a first supporting board. Next, the first resin layer is cut on the first supporting board, to make the devices separable from each other. The devices covered with the first resin layer are then peeled from the first supporting board, and transferred to a second supporting board. The devices thus transferred to the second supporting board are then with a second resin layer. Electrodes are formed in the first and second resin layers in such a manner that the electrodes are connected to the devices. The method then involves cutting the second resin layer to obtain resin buried devices each containing at least one of the devices. The resin buried devices are peeled from the second supporting board, and transferred to a device transfer body.  
         [0014]     With this configuration, the resin buried device being handled has a size larger than that of the device itself. The larger size of the resin buried device facilitates the handling of the devices in the transfer step. Since the electrode is formed in the first and second resin layers in such a manner as to be connected to the device, it is possible to easily form the electrode and to prevent occurrence of connection failures between the electrode and an external electrode by increasing the area of the electrode. Since respective resin buried devices are obtained by cutting only the first and second resin layers without the need of cutting the substrate, it is possible to easily obtain the resin buried devices because the first and second resin layers can be easily, smoothly cut. Further, the substrate, which is not cut, can be reused.  
         [0015]     According to a fourth embodiment of the present invention, a panel including an array of resin buried devices is provided. Resin buried device contains at least one device. A plurality of the devices are formed on a substrate and are covered with a resin layer. The resin layer is cut to obtain the resin buried devices each containing at least one of the devices. Furthermore, the resin buried devices are peeled from the substrate and are transferred to the panel.  
         [0016]     With this configuration, it is possible to provide an inexpensive panel.  
         [0017]     In the above device transfer method, preferably, connection holes are formed in the resin layer in a manner such as to reach the devices by laser beams, and the electrodes are connected to the devices via the connection holes. With this configuration it is possible to prevent the resin layer covering the device from being thinned and hence to improve the strength of the resin buried device.  
         [0018]     In the device transfer method, preferably, the electrodes are each formed with their planar dimension substantially corresponding to a planar dimension of each of the resin buried devices, and the resin layer is cut by laser beams with the electrodes taken as a mask, to obtain the resin buried devices. With this configuration, it is possible to eliminate the need of use of a laser system having a high accurate positioning function and hence to reduce the production cost of the devices.  
         [0019]     Additional features and advantages of the present invention are described in, and will be apparent from, the following Detailed Description of the Invention and the figures. 
     
    
     BRIEF DESCRIPTION OF THE FIGURES  
       [0020]      FIGS. 1A  to  1 C are sectional views showing steps of a device transfer method according to a first embodiment of the present invention, wherein  FIG. 1A  shows a state in which a sapphire substrate, on which each device has been formed, is coated with a resin,  FIG. 1B  shows a state in which the resin is hardened, and  FIG. 1C  shows a state in which an interface between the device and the sapphire substrate is irradiated with laser beams having come from a back surface side of the sapphire substrate;  
         [0021]      FIGS. 2A  to  2 C are sectional views showing steps continued from the step shown in  FIG. 1C , wherein  FIG. 2A  shows a state in which the device is peeled from the sapphire substrate and is transferred to a first supporting board,  FIG. 2B  shows a state in which gallium remaining on the device is etched, and  FIG. 2C  shows a state in which device separation grooves are formed by oxygen plasma;  
         [0022]      FIGS. 3A  to  3 C are sectional views showing steps continued from the step shown in  FIG. 2C , wherein  FIG. 3A  shows a state in which the first supporting board is coated with a resin,  FIG. 3B  shows a state in which the resin is selectively irradiated with ultraviolet rays and a polyimide layer is selectively irradiated with laser beams, and  FIG. 3C  shows a state in which the devices are selectively transferred to a second supporting board;  
         [0023]      FIGS. 4A  to  4 C are sectional views showing steps continued from  FIG. 3C , wherein  FIG. 4A  shows a state in which each device is covered with a second resin layer,  FIG. 4B  shows a state in which the first and second resin layers are etched, and  FIG. 4C  shows a state in which an electrode connected to the device is formed;  
         [0024]      FIGS. 5A  to  5 C are sectional views showing steps continued from  FIG. 4C , wherein  FIG. 5A  shows a state in which a polyimide layer formed on the second supporting board is irradiated with laser beams,  FIG. 5B  shows a state in which the devices are transferred to the third supporting board, and  FIG. 5C  shows a state in which the resin layers are etched;  
         [0025]      FIGS. 6A  to  6 C are sectional views showing steps continued from  FIG. 5C , wherein  FIG. 6A  shows a state in which an electrode connected to each device is formed,  FIG. 6B  shows a state in which the resin layers are cut by laser beams, and  FIG. 6C  shows a state in which resin buried devices are peeled from the third supporting board;  
         [0026]      FIGS. 7A and 7B  are sectional views showing steps continued from  FIG. 6C , wherein  FIG. 7A  shows a state in which each resin buried body is bonded to a device transfer body, and  FIG. 7B  shows a state in which a resin buried device of another kind is bonded to the same device transfer body;  
         [0027]      FIGS. 8A and 8B  are sectional views showing steps continued from  FIG. 7B , wherein  FIG. 8A  shows a state in which an interlayer insulating film is formed, and  FIG. 8B  shows a state in which wiring is formed;  
         [0028]      FIGS. 9A  to  9 D are sectional views showing steps continued from the step shown in  FIG. 3C , according to a second embodiment of the present invention, wherein a connection hole is formed in the resin layers by laser beams;  
         [0029]      FIGS. 10A and 10B  are sectional views showing steps continued from the step shown in  FIG. 5C , according to a third embodiment, wherein the resin layers are cut by laser means with the electrode taken as a mask;  
         [0030]      FIGS. 11A and 11B  are views showing a light emitting device used in the embodiments of the present invention, wherein  FIG. 11A  is a sectional view and  FIG. 11B  is a plan view; and  
         [0031]      FIG. 12  is a sectional view showing a related art method of cutting a gallium nitride based semiconductor wafer. 
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0032]     Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.  
         [0033]     First, there will be described devices used for carrying out the present invention with reference to  FIGS. 11A and 11B , which devices are exemplified by light emitting diodes representative of light emitting devices in the following embodiments.  FIG. 11A  is a sectional view of such a light emitting diode and  FIG. 11B  is a plan view of the light emitting diode. As shown in these figures, a light emitting diode  2  is made from a gallium nitride (GaN) based semiconductor and is formed by crystal growth on a device formation substrate, for example, a sapphire substrate  1 .  
         [0034]     An under growth layer  51  made from a GaN based semiconductor is formed on the sapphire substrate  1 , and a hexagonal pyramid shaped GaN layer  52  doped with silicon is formed on the under growth layer  51  as follows: namely, an insulating film  53  is formed on the under growth layer  51 , and a GaN layer  52  for one device is selectively grown, by an MOCVD (Metal-organic Chemical Vapor Deposition) process, from one of openings formed in the insulating film  53  in such a manner as to be separated from a GaN layer  52  for another device. In the case of taking a C-plane of sapphire as a principal plane of the sapphire substrate  1 , the GaN layer  52  becomes a hexagonal pyramid shaped growth layer surrounded by an S-plane, that is, a ( 1 - 101 ) plane  52   a.    
         [0035]     A portion of the inclined S-plane  52   a  of the GaN layer  52  functions as a cladding of a double-hetero structure. An InGaN layer  54  is formed as an active layer on the GaN layer  52  in such a manner as to cover the S-plane  52   a.  A GaN layer  55  doped with magnesium is formed on the InGaN layer  54 . The GaN layer  55  functions as a cladding.  
         [0036]     A metal material such as Ni, Pt, Au, or Pb is vapor-deposited on the GaN layer  55 , to form a p-electrode  56 . An n-electrode will be formed on a back surface side of the under growth layer  51  during a transfer step to be described later.  
         [0037]     The above described light emitting diode  2  is configured, for example, as a light emitting diode of blue (B). The structure of the light emitting diode  2  is not limited to that described above but may be a structure in which an active layer is formed into a flat plate or band shape, or be a pyramid structure with a C-plane formed on its upper end portion. The material of the light emitting diode  2  is not limited to a GaN based material, either, but may be any other nitride based material or any other compound semiconductor.  
         [0038]     A device transfer method according to a first embodiment of the present invention will be described below with reference to FIGS.  1  to  8 . The light emitting diodes  2  shown in  FIGS. 11A and 11B  are used as devices to be transferred by the device transfer method according to the first embodiment.  
         [0039]     Referring to  FIG. 1A , a plurality of light emitting diodes  2 , each having the same structure as that shown in  FIGS. 11A and 11B , are densely formed on a principal plane of a sapphire substrate  1  having a diameter of, for example, two inches in such a manner as to be arrayed in rows and columns, that is, into a matrix. Each light emitting diode  2  has a size about 20 μm square. The light emitting diodes  2  are in a state being separable from each other by device separation grooves  4  formed by reactive ion etching or the like.  
         [0040]     The sapphire substrate  1  is coated with an ultraviolet curing type resin  3 , and a polyimide layer  6  formed on a surface of a quartz glass board  5  as a first supporting board is brought into press-contact with the ultraviolet curing type resin  3 .  
         [0041]     Referring to  FIG. 1B , the ultraviolet curing type resin  3  is irradiated with ultraviolet rays having come from a back surface side of the quartz glass board  5  side, to be hardened, whereby a first resin layer  3 ′ is formed. The light emitting diodes  2  are thus collectively covered with the first resin layer  3 ′.  
         [0042]     Referring to  FIG. 1C , interfaces between the GaN based under growth layers  51  of the light emitting diodes  2  and the sapphire substrate  1  are irradiated with laser beams having come from a back surface side of the sapphire substrate  1 . At this time, GaN at each interface is decomposed into nitrogen and gallium and the gaseous nitrogen is released therefrom, so that the bond of each light emitting diode  2  to the sapphire substrate  1  is released. Consequently, as shown in  FIG. 2A , the light emitting diodes  2  are collectively peeled from the sapphire substrate  1 . With respect to the first resin layer  3 ′ covering the light emitting diodes  2 , bonds of molecules constituting the resin layer  3 ′ are cut at the interfaces by the same laser abrasion effect. As a result, the resin layer  3 ′ is peeled, together with the light emitting diodes  2 , from the sapphire substrate  1 .  
         [0043]     As shown in  FIG. 2A , only gallium (Ga)  7  remains on the peeling surface on the light emitting diode  2  side, which gallium is then removed by wet etching or the like as shown in  FIG. 2B .  
         [0044]     Referring to  FIG. 2C , device separation grooves  8 , each extending from the device separation groove  4  to the quartz glass board  5 , are formed by etching the first resin layer  3 ′ by using oxygen plasma. The formation of the device separation grooves  8  makes the light emitting diodes  2  separable from each other. In this plasma etching, since an erosion effect of oxygen plasma to the under growth layer  51  is significantly smaller than that to the first resin layer  3 ′, the device separation grooves  8  are formed with the under growth layer  51  taken as a mask.  
         [0045]     Referring to  FIG. 3A , the light emitting diodes  2  covered with the first resin layer  3 ′ are coated with an ultraviolet curing type resin  9 , and a polyimide layer  11  formed on a surface of a quartz glass board  10  as a second supporting board is brought into press-contact with the ultraviolet curing type resin  9 .  
         [0046]     Referring to  FIG. 3B , the ultraviolet curing type resin  9  is selectively irradiated with ultraviolet rays having come from a back surface of the quartz glass board  10 . It is to be noted that only one position of the ultraviolet curing type resin  9 , which corresponds to a position of the central light emitting diode  2 , is irradiated with ultraviolet rays in  FIG. 3B ; however, in actual, positions of the ultraviolet curing type resin  9 , which correspond to positions of the light emitting diodes  2  spaced from each other at intervals of, for example, ten pieces, are selectively irradiated with ultraviolet rays. The portion, irradiated with ultraviolet rays, of the ultraviolet curing type resin  9  is hardened, whereby a resin layer  9 ′, which bonds the light emitting diode  2  covered with the first resin layer  3 ′ to the polyimide layer  11  formed on the quartz glass board  10 , is formed.  
         [0047]     An interface between the polyimide layer  6  and the quartz glass board  5  is irradiated with laser beams having come from a back surface side of the quartz glass board  5 . At this time, the polyimide layer  6  is peeled from the quartz glass board  5  or internally peeled by the laser abrasion effect. In this way, as shown in  FIG. 3C , although the light emitting diodes  2 , each having the size of about 20 μm square, are densely arrayed on the quartz glass board  5  as the first supporting board, those spaced from each other at the intervals of ten pieces are transferred to the quartz glass board  10  as the second supporting board while being arrayed with an enlarged pitch of about 200 μm. It is to be noted that only one light emitting diode  2  is shown in  FIG. 3C ; however, in actual, the light emitting diodes  2  covered with the first resin layer  3 ′ on the quartz glass board  5 , which are spaced from each other at the intervals of 10 pieces, are simultaneously transferred to the quartz glass substrate  10 . In addition, the light emitting diodes  2 , which are adjacent to those having been transferred, remain on the quartz glass substrate  5 ; however, they will be all transferred to other quartz glass boards  10 .  
         [0048]     Referring to  FIG. 4A , all of the light emitting diodes  2  (covered with the first resin layer  3 ′) having been transferred to the quartz glass substrate  10  are collectively covered with a second resin layer  12 . The second resin layer  12  is formed, for example, by hardening an ultraviolet curing type resin by ultraviolet rays.  
         [0049]     As shown in  FIG. 4B , the second resin layer  12 , the polyimide layer  6 , and the first resin layer  3 ′ are etched back by using oxygen plasma, to expose the p-electrode  56  of the light emitting diode  2 , and then the surfaces of the p-electrode  56  and the first and second resin layers  3 ′ and  12 , on which an extraction electrode to be described later is to be formed, are cleaned.  
         [0050]     Referring to  FIG. 4C , an extraction electrode  13  is formed on the first and second resin layers  3 ′ and  12  in such a manner as to be connected to the p-electrode  56  of the light emitting diode  2 . The extraction electrode  13  is formed by depositing a transparent material made from a metal or ITO (Indium Tin Oxide) by vapor-deposition or sputtering and patterning the deposited material into a specific planar shape having a specific size by photolithography and wet etching.  
         [0051]     Referring to  FIG. 5A , a quartz glass board  14  as a third supporting board is fixed to a surface side, on which the extraction electrode  13  has been formed, of the second resin layer  12  via a polyimide layer  15  formed on a surface of the quartz glass board  14 . An interface between the polyimide layer  11  and the quartz glass board  10  is irradiated with laser beams having come from a back surface side of the quartz glass board  10 , so that the polyimide layer  11  is peeled from the quartz glass board  10  or internally peeled by the laser abrasion effect (see  FIG. 5B ). In this way, the light emitting diodes  2  on the quartz glass board  10  as the second supporting board are collectively transferred, together with the resin layers  3 ′ and  12  covering the light emitting diodes  2 , to the quartz glass board  14  as the third supporting board. As will be described below, this transfer step is carried out for forming an extraction electrode on the n-electrode side opposite to the extraction electrode  13  on the p-electrode side.  
         [0052]     Referring to  FIG. 5C , the polyimide layer  11  and the second resin layer  12  are etched back by oxygen plasma, to expose the under growth layer  51  of the light emitting diode  2 , and then surfaces of the under growth layer  51  and the second resin layer  12 , on which an extraction electrode on the n-electrode side is to be formed as described below, are cleaned.  
         [0053]     Referring to  FIG. 6A , an extraction electrode  16  is formed on the second resin layer  12  in such a manner as to be connected to the under growth layer  51  of the light emitting diode  2 . The extraction electrode  16  is formed by depositing a transparent material such a metal or ITO by vapor-deposition or sputtering and patterning the deposited material into a specific planar shape having a specific size by lithography and wet etching.  
         [0054]     Referring to  FIG. 6B , device separation grooves  17  are formed by cutting the second resin layer  12  and the polyimide layer  15  by laser beams L emitted from an excimer laser system or a third harmonic YAG laser system, to obtain each resin buried device  20  in which the light emitting diode  2  is covered with the resin layer. In accordance with this embodiment, each resin buried device  20  containing one light emitting diode  2  has a planar size of about 160 μm square and has a thickness of several tens μm.  
         [0055]     Referring to  FIG. 6C , an interface between the quartz glass board  14  and the polyimide layer  15  is irradiated with laser beams having come from a back surface of the quartz glass board  14 . It is to be noted that only one resin buried device  20  is irradiated with laser beams in  FIG. 6C ; however, in actual, the resin buried devices  20  spaced from each other at intervals of, for example, three pieces are selectively irradiated with laser beams, and portions, irradiated with laser beams, of the polyimide layer  15  are peeled from the interface with the quartz glass board  14  or internally peeled by the laser abrasion effect.  
         [0056]     The resin buried device  20  is then attracted by a vacuum chuck  21  having a suction hole  21   a,  and is transferred, as shown in  FIG. 7A , to a panel  50  of a display unit as a device transfer body. The suction holes  21   a  are arrayed in rows and columns with pitches corresponding to those of pixels of a display unit, that is, arrayed into a matrix corresponding to that of the pixels, to collectively attract the peeled resin buried devices  20  spaced from each other at the intervals of three pieces from the quartz glass board  14 . Concretely, the suction holes  21   a  are arrayed into a matrix with a pitch of 600 μm, which can simultaneously attract about 300 pieces of the resin buried devices  20 .  
         [0057]     That is to say, of the resin buried devices  20  arrayed with a pitch of about 200 μm on the quartz glass board  14  as the third supporting board, those spaced from each other at the intervals of three pieces are transferred to the device transfer body or panel  50  in such a manner as to be arrayed with an enlarged pitch of about 600 μm. It is to be noted that the other resin buried devices  20  remaining on the quartz glass board  14  will be all transferred to other positions of the same device transfer body  50  or other device transferred bodies.  
         [0058]     The device transfer body  50  includes an insulating substrate  29 , wiring layers  30   a  to  30   c,  an insulating layer  28  formed on the insulating substrate  29  in such a manner as to cover the wiring layers  30   a  to  30   c,  a wiring layer  27  formed on the insulating layer  28 , and a thermoplastic resin layer  26  formed on the wiring layer  27 . The resin buried device  20  is brought into press-contact with the thermoplastic resin layer  26 . A portion, being in press-contact with the resin buried device  20 , of the thermoplastic resin layer  26  is softened by irradiating it with infrared rays having come from a back surface side of the insulating substrate  29 , whereby the resin buried device  20  is fixed to the thermoplastic resin layer  26 .  
         [0059]     After that, as shown in  FIG. 7B , resin buried devices  31  containing, for example, light emitting diodes  22  of red (R) are transferred, in accordance with the same manner as that described above, to the device transfer body  50  in such a manner as to be arrayed in a matrix with a pitch of about 600 μm. Subsequently, while not shown, resin buried devices containing light emitting diodes of green (G), control transistors, and the like are similarly transferred to the device transfer body  50 .  
         [0060]     Referring to  FIG. 8A , an insulating resin layer  33  is formed in such a manner as to cover the resin buried devices, the control transistors, and the like. Then, as shown in  FIG. 8B , connection holes  34 ,  35 ,  36 ,  37 ,  38 , and  39  are formed in the insulating resin layer  33 . By use of these connection holes, an extraction electrode  32   a  of the resin buried device  31  is connected to the wiring layer  27  by means of wiring  40 ; an extraction electrode  32   b,  formed on the same surface side as that on which the extraction electrode  32   a  is formed, of the resin buried device  31  is connected to the extraction electrode  13  of the resin buried device  20  by means of wiring  41 ; and the extraction electrode  16  of the resin buried device  20  is connected to the wiring layer  30   c  by means of wiring  42 . A protective layer and the like are finally formed, to obtain a display panel in which the light emitting diodes of red (R), green (G), and blue (B) covered with the resin are arrayed in rows and columns with pitches corresponding to pixel pitches, that is, arrayed into a matrix corresponding that of pixels.  
         [0061]     As described above, according to this embodiment, since the light emitting diodes  2 , each having the very small size about 20 μm square, are densely formed on the sapphire substrate  1  as the device formation substrate, the number of the light emitting diodes  2  per one substrate can be made large. This makes it possible to reduce the product cost of one light emitting diode and hence to reduce the cost of a display unit using the light emitting diodes. Since the light emitting diode is transferred to the device transfer body  50  in the form of the resin buried device having the size about 160 μm square, it is possible to easily handle the light emitting diodes in the transfer step. The resin layer covering the light emitting diode  2  serves to protect the light emitting diode. The enlargement of the size of the light emitting diode  2  by covering the diode  2  with the resin layer is advantageous in that the extraction electrodes  13  and  16  can be easily formed, and that the planar sizes of the extraction electrodes  13  and  16  can be enlarged enough to prevent occurrence of any wiring failure at the time of wiring the extraction electrodes  13  and  16  to the device transfer body  50  side, to improve the reliability of wiring thereof to the device transfer body  50  side.  
         [0062]     In the above embodiment, in place of cutting the hard sapphire substrate  1 , the first and second resin layers  3  and  12  are cut by laser beams, to separate an array of the light emitting diodes  2  into individual devices to be transferred (resin buried devices). With this configuration, since the resin layer can be easily and accurately cut by the laser abrasion effect, it is possible to separate an array of the light emitting diodes  2  into individual devices having accurate shapes and sizes without a lot of labor and time paid for cutting.  
         [0063]     A second embodiment of the present invention will be described with reference to  FIGS. 9A  to  9 D. It is to be noted that parts corresponding to those described in the first embodiment are designated by the same reference numerals and the overlapped description thereof is omitted.  
         [0064]      FIG. 9A  shows a step equivalent to the step shown in  FIG. 4A  according to the first embodiment. According to this embodiment, however, the process goes on from the step shown in  FIG. 9A  to a step shown in  FIG. 9B , in which the second resin layer  12 , the polyimide layer  6  and the first resin layer  3 ′ are etched back by oxygen plasma to an extent that the p-electrode  56  of the light emitting diode  2  is not exposed, and then the surfaces of the first and second resin layers  3 ′ and  12 , on which an extraction electrode to be described later is to be formed, are cleaned.  
         [0065]     Referring to  FIG. 9C , a connection hole  23  is formed in the first resin layer  3 ′ by laser beams emitted by an excimer laser system or a third harmonic YAG laser system, to expose the p-electrode  56  of the light emitting diode  2 . Referring to  FIG. 9D , an extraction electrode  13 ′ is formed on the first and second resin layers  3 ′ and  12  in such a manner as to be connected to the p-electrode  56  via the connection hole  23 . The material of the extraction electrode  13 ′ and the formation method thereof are the same as those described in the first embodiment. Subsequent steps are also the same as those described in the first embodiment.  
         [0066]     According to the first embodiment, as shown in  FIG. 4B , the first and second resin layers  3 ′ and  12  are etched back until the p-electrode  56  is exposed, and correspondingly, the thicknesses of the first and second resin layers  3 ′ and  12  for covering and protecting the light emitting diode  2  become thin, so that the rigidity of the resin buried device  20  obtained in the subsequent step becomes weak. This may often cause a difficulty in handling the resin buried device  20  at the time of picking up the resin buried device  20  by the vacuum chuck  21  for transferring it to the device transfer body  50 .  
         [0067]     To cope with such an inconvenience, according to the second embodiment, as described above, the connection hole  23  for exposing the p-electrode  56  therethrough is locally formed in the first and second resin layers  3 ′ and  12 , with a result that as compared with the first embodiment, the thickness of the first and second resin layers  3 ′ and  12  become thicker and thereby the strengths thereof become larger. Another advantage of formation of the connection hole  23  is as follows. Since an etching rate of the ultraviolet curing resin forming each of the first and second resin layers  3 ′ and  12  by oxygen plasma is small, it takes a lot of time to etch back the first and second resin layers  3 ′ and  12 . Meanwhile, the use of laser beams can form the connection hole in a resin layer for a short time irrespective of a material forming the resin layer. Accordingly, as compared with the manner in the first embodiment that the first and second resin layers  3 ′ and  12  are etched back by oxygen plasma until the p-electrode  56  is exposed, the manner in the second embodiment that the first and second resin layers  3 ′ and  12  are etched back by oxygen plasma to an extent that the p-electrode  56  is not exposed and then the connection hole  23  is formed in the first and second resin layers  3 ′ and  12  by laser beams so as to expose the p-electrode  56  therethrough is advantageous in that the time required to expose the p-electrode  56  can be shorten, and that the degree of freedom in selection of materials for forming the first and second resin layers  3 ′ and  12  can be increased, leading to the reduced material cost.  
         [0068]     It to be noted that the step shown in  FIG. 9B  may be replaced with a step in which the connection hole  23  is directly formed in the second resin layer  12 , the polyimide layer  6 , and the first resin layer  3 ′ in the state shown in  FIG. 9A . However, the cleaning of the surfaces, on which the extraction electrode  13 ′ is to be formed, by oxygen plasma as in the step shown in  FIG. 9B  is advantageous in increasing the adhesive strength of the extraction electrode  13 ′ to the resin layers.  
         [0069]     A third embodiment of the present invention will be described below with reference to  FIGS. 10A and 10B . It is to be noted that parts corresponding to those described in the first embodiment are designated by the same reference numerals and the overlapped description thereof is omitted.  
         [0070]     According to the third embodiment, the process goes on from the step shown in  FIG. 5C  in the first embodiment to a step shown in  FIG. 10A , in which an extraction electrode  16 ′ to be connected to the under growth layer  51  of the light emitting diode  2  is formed on the second resin layer  12 , wherein a planar size of the extraction electrode  16 ′ is set to be equal to that of a resin buried device  20 ′ obtained in the next step, that is, set to a square shape having a size 160 μm square. Like the first embodiment, the extraction electrode  16 ′ is formed by depositing a transparent material such as a metal or ITO by sputtering and patterning the deposited material into a planar shape having the above-described specific size by photolithography and wet etching.  
         [0071]     In the next step shown in  FIG. 10B , device separation grooves  17  are formed by cutting the second resin layer  12  and the polyimide layer  15  by laser beams L emitted from an excimer laser system or a third harmonic YAG laser system with the extraction electrode  16 ′ taken as a mask, to obtain each resin buried device  20 ′ in which the light emitting diode  2  is covered with the resin layer. Subsequent steps are the same as those described in the first embodiment.  
         [0072]     In the step shown in  FIG. 6B  according to the first embodiment, the device separation grooves  17  are formed by identifying alignment marks formed, for example, at diagonal positions on the laser system side and performing accurate NC control of the laser system on the basis of the identified alignment marks. In this case, the laser system side must be operated at a high positioning accuracy in the order of 1 μm. On the contrary, according to the third embodiment, since the extraction electrode  16 ′ formed so as to have the same planar shape and planar size as those of the resin buried device  20 ′ to be separated is used as the mask, the laser system side does not require a high positioning accuracy and a cross-sectional diameter of a laser beam may be relatively large. For example, the laser system side may be operated at a positioning accuracy in the order of 10 μm. According to this embodiment, therefore, it is possible to eliminate the need of use of an expensive, accurate laser system and hence to reduce the production cost. Further, the third embodiment can be carried out without addition of any step to the first embodiment.  
         [0073]     While the embodiments of the present invention have been described, the present invention is not limited thereto, and it is to be understood that many changes may be made without departing from the technical thought of the present invention.  
         [0074]     The device used for carrying out the present invention is not limited to the light emitting diode described in the embodiments, but may be a laser diode, a thin film transistor device, an photoelectric conversion device, a piezoelectric device, a resistance device, a switching device, a micro-magnetic device, or a micro-optical device.  
         [0075]     In the light emitting diode described in the embodiments of the present invention, the substrate, on which a crystal growth layer is to be grown, is not particularly limited insofar as an active layer having good crystallinity can be formed thereon. Examples of materials for forming the substrates may include sapphire (Al2O3; containing an A-plane, R-plane, and C-plane), SiC (including 6H, 4H, and 3C), GaN, Si, ZnS, ZnO, AlN, LiMgO, GaAs, MgAl2O4, and InAlGaN. The above material having a hexagonal or cubic system is preferably used, and a substrate made from the above material having a hexagonal system is more preferably used. For example, in the case of using a sapphire substrate, the C-plane of sapphire, which has been often used for growing a gallium nitride (GaN) based compound semiconductor thereon, may be used as a principal plane of the substrate. The C-plane as the principal plane of the substrate may contain a plane orientation tilted in a range of 5 to 6°. The substrate may not be contained in a light emitting device as a final product. For example, the substrate may be used for holding a device portion in the course of production and be removed before accomplishment of the device.  
         [0076]     In the light emitting diode described in the embodiments of the present invention, the crystal growth layer formed by selective growth on the substrate preferably has a crystal plane tilted to the principal plane of the substrate. The crystal growth layer may be a material layer containing a light emission region composed of a first conductive layer, an active layer, and a second conductive layer. In particular, the crystal growth layer, preferably and thereby not limited thereto, has a wurtzite crystal structure. Such a crystal layer can be made from, for example, a group III based compound semiconductor, a BeMgZnCdS based compound semiconductor, a BeMgZnCdO based compound semiconductor, a gallium nitride based compound semiconductor, an aluminum nitride (AlN) based compound semiconductor, indium nitride (InN) based compound semiconductor, an indium gallium nitride (InGaN) based compound semiconductor, or aluminum gallium nitride (AlGaN) based compound semiconductor. In particular, a nitride based semiconductor such as a gallium nitride based compound semiconductor is preferably used as the material for forming the above crystal layer. It is to be noted that InGaN or AlGaN, or GaN does not necessarily mean only a nitride based semiconductor of ternary mixed crystal or binary mixed, but may be a nitride based semiconductor containing other impurities in amounts not to affect the nitride based semiconductor. For example, InGaN may contain Al and another impurity in slight amounts not to affect InGaN.  
         [0077]     In the light emitting diode described in the embodiments, the peeling layer to be interposed between the substrate and the device is made from polyimide; however, it may be made from another resin, particularly, a high molecular resin. Examples of the high molecular resins may include polyacetylene, polyamide, polyether sulphone, polycarbonate, polyethylene, polyethyleneterephthalate, polymethyl methacrylate, polystyrene, polyvinyl chloride, polyester, polyether, epoxy resin, polyolefin, and polyacrylate. These materials may be used singly or in combination of two or more kinds.  
         [0078]     Although each of the first and second resin layers  3 ′ and  12  is made from an ultraviolet curing type resin in the embodiments, it may be made from a thermoplastic resin or a thermosetting resin. The use of an ultraviolet curing type resin, however, is advantageous in that since an ultraviolet curing type resin does not require any heat at the hardening stage, it is not thermally contracted or expanded. As a result, the device is not affected by a stress caused by hardening the resins forming the first and second resin layers  3 ′ and  12 , and can be produced at a high dimensional accuracy.  
         [0079]     Each of the first, second, and third supporting boards  5 ,  10  and  14  is not limited to the quartz glass board described in the embodiments, but may be a board of another type, for example, a plastic board.  
         [0080]     The transfer of the resin buried devices  20  to the device transfer body  50  may be performed in accordance with a manner different from that described in the embodiment. Specifically, the resin buried devices  20  may be individually peeled from the third supporting board  14  once, and then transferred to the device transfer body  50  one by one.  
         [0081]     It is to be noted that the third embodiment may be combined with the second embodiment.  
         [0082]     While a preferred embodiment of the present invention has been described using specific terms, such description is for illustrative purposes only, and it is to be understood that changes and variations may be made without departing from the spirit or scope of the following claims.  
         [0083]     It should be understood that various changes and modifications to the presently preferred embodiments described herein will be apparent to those skilled in the art. Such changes and modifications can be made without departing from the spirit and scope of the present invention and without diminishing its intended advantages. It is therefore intended that such changes and modifications be covered by the appended claims.