Abstract:
The present invention proposes variations of the laser separation method allowing separating homoepitaxial films from the substrates made from the same crystalline material as the epitaxial film. This new method of laser separation is based on using the selective doping of the substrate and epitaxial film with fine donor and acceptor impurities. In selective doping, concentration of free carries in the epitaxial film and substrate may essentially differ and this can lead to strong difference between the light absorption factors in the infrared region near the residual beams region where free carriers and phonon-plasmon interaction of the optical phonons with free carriers make an essential contribution to infrared absorption of the optical phonons. With the appropriate selection of the doping levels and frequency of infrared laser radiation, it is possible to achieve that laser radiation is absorbed in general in the region of strong doping near the interface substrate-homoepitaxial film. When scanning the interface substrate-homoepitaxial film with the focused laser beam of sufficient power, thermal decomposition of the semiconductor crystal takes place with subsequent separation of the homoepitaxial film. The advantage of the proposed variations of the method for laser separation of epitaxial films in comparison with the known ones is in that it allows the separation of homoepitaxial films from the substrates, i.e., homoepitaxial films having the same width of the forbidden gap as the initial semiconductor substrate has. The proposed variations of the method can be used for separation of the epitaxial films.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
       [0001]    This application is a divisional application of U.S. application Ser. No. 14/129,594, filed on Dec. 27, 2013; which claims benefit of the U.S. National Phase of International Patent Application No. PCT/RU2012/000588, filed on Jul. 13, 2012; which claims benefit of Russian Patent Application No. 2011129184, filed on Jul. 13, 2011, the contents of which are incorporated herein by reference in their entireties. 
     
    
     TECHNICAL FIELD 
       [0002]    Group of the inventions relates to the laser treatment of the solid materials, in particular, to the method of separation of the semiconductors&#39; surface layers with laser radiation, namely the laser separation of the epitaxial film or of the epitaxial film layer from the growth substrate of the epitaxial semiconductor structure. 
       BACKGROUND ART 
       [0003]    Laser separation of the epitaxial layers of the semiconductor crystals from the growth substrates with their transfer on to the ungrowth substrates is widely used now in manufacturing of the light diodes (patents U.S. Pat. No. 7,241,667, U.S. Pat. No. 7,202,141) and laser diodes (U.S. Pat. No. 6,365,429) according to the flip-chip technology. 
         [0004]    In the first time, laser separation of the gallium nitride layers from the transparent growth sapphire substrates was proposed in the work Kelly et al Physica Status Solidi (a) vol. 159, pp. R3, R4, (1997). In this work the ultraviolet excimer laser with wave length λ=355 nm satisfying the ratio 2πhc/E g1 &lt;λ&lt;2πhc/E g2  was used, for which the quantum energy is within the forbidden gap of the substrate E g1  made of sapphire, but exceeds the width of the forbidden gap of the epitaxial film E g2 , consisting of gallium nitride. 
         [0005]    Later, the method of laser separation based on the difference between the widths of the forbidden gaps of the growth substrate and epitaxial film was improved. In particular, to improve quality of the separated epitaxial film and to suppress its cracking, it was proposed to use additional sacrifial layer with the width of the forbidden gap less than the widths of the forbidden gaps of the growth substrate and epitaxial film, as well to use scanning of the heteroepitaxial interface between the growth substrate and epitaxial film (patents U.S. Pat. No. 6,071,795, U.S. Pat. No. 6,365,429). 
         [0006]    The general scheme of the laser separation methods based on the difference between the widths of the forbidden gaps of the growth substrate and epitaxial film is shown in  FIG. 1 . 
         [0007]    When exposing to ultraviolet from the side of the substrate from heteroepitaxial semiconductor gallium nitride film  102  grown on the substrate  101  of sapphire having the width of the forbidden gap more than the light quantum energy, ultraviolet laser radiation passes through sapphire and is absorbed in the thin layer of gallium nitride nearby the heteroepitaxial interface  105  gallium nitride—sapphire. On exposure to ultraviolet laser radiation, gallium nitride in the area  104  defined by crossing of the ultraviolet laser radiation  103  with heteroepitaxial interface  105  is heated up to the temperature T 1 , exceeding the decomposition temperature T 0 ˜900° C., and decomposes into gaseous nitrogen and liquid gallium, and as a result epitaxial film of gallium nitride separates from sapphire. 
         [0008]    All before proposed methods of laser separation of epitaxial films from the growth substrates are based on the difference between the widths of the forbidden gaps of the epitaxial film E g2  and substrate E g1 . These methods can be successfully used for separating the epitaxial films obtained using heteroepitaxy method, i.e., technology of growing the epitaxial film onto the growth substrate made of the material which differs from the epitaxial film material. 
         [0009]    However, to obtain high quality epitaxial films without integrated mechanical stresses, it is often happened to be necessary to use a homoepitaxy method, which provides growing of the epitaxial film on the growth substrate from the same material as the epitaxial film. In this case growth substrate and epitaxial film have an equal width of the forbidden gap, and the usual laser separation method disclosed above becomes unapplied. 
         [0010]    The object of the present invention is an expansion of the method application field, namely providing the possibility of separating the epitaxial films from the substrates made of the same crystal material as the epitaxial film. 
       SUMMARY OF INVENTION 
       [0011]    To solve this object, two variations of the method for laser separation of the epitaxial film or epitaxial film layer from the growth substrate of the epitaxial semiconductor structure were proposed. 
         [0012]    In the first variation of the method in growing the epitaxial film or epitaxial film layer, selective doping with small donor or acceptor impurities of some areas of the epitaxial structure is used, so that the resulting concentration of the small impurities in the selectively doped areas substantially exceeds the background concentration in the undoped areas. Then, the focused laser beam is directed onto the epitaxial structure consisting of the substrate and epitaxial film so that the beam focus is placed in the selectively doped areas of the crystal structure in which absorption of the laser radiation takes place. Laser beam is moved with scanning the selectively doped areas of the epitaxial structures with beam focus with partial thermal decomposition of selectively doped areas and decreasing their mechanical strength. After laser scanning the epitaxial structure is glued on the temporary substrate and the epitaxial film or the epitaxial film layer is separated from the growth substrate or the growth substrate with a part of the epitaxial film by applying mechanical or thermomechanical stress. 
         [0013]    The second variation of the method is characterized by the same features, and differs from the first method in that the epitaxial structure is glued on the temporary substrate before laser scanning, then laser scanning of the epitaxial structure glued on the temporary substrate is performed, and after laser scanning the epitaxial film or the epitaxial film layer is separated from the growth substrate or the growth substrate with a part of the epitaxial film by applying mechanical or thermomechanical stress. 
         [0014]    Preferably, the epitaxial film or the epitaxial film layer is grown by the homoepitaxy method. 
         [0015]    Preferably, the selectively doped area is the substrate or the surface layer of the substrate. 
         [0016]    Preferably, the selectively doped area is the epitaxial film or the lower layer of the epitaxial film. 
         [0017]    Preferably, the material of the crystalline structure consisting of the substrate and epitaxial film, is the semiconductor from the elements of the forth group or the semiconductor compound from the elements of the forth group, or the semiconductor compound from the elements of the third and fifth group, or the semiconductor compound from the elements of the second and sixth group of the periodic system. 
         [0018]    Preferably, the laser wave length for separating the homoepitaxial films from the growth substrate is in the following wave length range: for silicon, germanium and gallium arsenide semiconductors in the range of 6 μm≦λ≦48 μm, for gallium nitride in the range of 4 μm≦λ≦32 μm, for silicon carbide 3 μm≦λ≦24 μm, for alumina nitride in the range of 2.5 μm≦λ≦20 μm, and for diamond 2 μm≦λ≦16 μm. 
         [0019]    Preferably, infrared gas pulse pumped silicon dioxide CO 2  or silicon oxide CO is used as a laser. 
         [0020]    The proposed variations of the laser separation method allow separating the homoepitaxial films from the substrates made of the same crystalline material as the epitaxial film. This new laser separation method is based on the usage of the selective doping of the substrate and epitaxial film with the fine donor or acceptor impurities. In the selective doping, concentrations of the free carriers in the epitaxial film and substrate may significantly differ, and this can lead to a strong difference between the light absorption factors in the infrared region near the region of the residual beams, where free carriers and phonon-plasmon interaction of the optical phonons with free carriers make an essential contribution to infrared absorption of the optical phonons. 
         [0021]    With the appropriate selection of the doping levels and frequency of infrared laser radiation it is possible to achieve that laser radiation is absorbed in general in the region of strong doping near the interface substrate-homoepitaxial film. When scanning the interface substrate-homoepitaxial film with the focused laser beam of sufficient power, thermal decomposition of the semiconductor crystal takes place with subsequent separation of the homoepitaxial film. 
         [0022]    To realize the proposed method of laser separation, it is preferably to use laser radiation with wave length λ being within the infrared region of relative transparence of the undoped semiconductor, namely near the edge of the residual beams region where a strong absorption of light at the expense of one- or two-phonon processes is not possible, but a relatively weak absorption of light may present at the expense of three- or more phonon processes. 
         [0023]    Preferably, wave length λ of the laser beam is within the range of c/4v 0 ≦λ≦2c/v 0 , where v 0  is a frequency of LO-optical phonon for a semiconductor material of the growth substrate, c is a light velocity. 
         [0024]    The inequality given above follows that the preferable laser wave length for separating the homoepitaxial films from the growth substrate is within the following wave length ranges: for silicon, germanium and gallium arsenide semiconductors in the range of 6 μm≦λ≦48 μm, for gallium nitride in the range of 4 μm≦λ≦32 μm, for silicon carbide 3 μm≦λ≦24 μm, for alumina nitride in the range of 2.5 μm≦λ≦20 μm, and for diamond 2 μm≦λ≦16 μm. 
         [0025]    The technical result of the proposed invention consists in offering a new method of laser separation of the epitaxial films in comparison with the known ones which allows to separate homoepitaxial films from the substrates, i.e., homoepitaxial films having the same width of the forbidden gap as the initial semiconductor substrate. Also, the proposed method allows using the high-effective and inexpensive infrared gas silicon dioxide CO 2  or silicon oxide CO lasers for separation of the epitaxial films. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0026]    The present invention is illustrated by the drawings in which the prior art is shown  FIG. 1 , schemes illustrating the realization of the present invention  FIG. 2-5 , and calculated spectral dependences of the light absorption factor in gallium nitride at various levels of doping with fine donor impurities  FIG. 6 . 
           [0027]      FIG. 1  shows the scheme of the known prior art method of laser separation of the heteroepitaxial film of semiconductor crystal from a foreign growth substrate using focused laser radiation with wave length λ for which a light quantum energy is within the forbidden gap of the substrate E g1 , and exceeds the width of the forbidden gap of the epitaxial film E g2  material. 
           [0028]      FIG. 2  shows a scheme illustrating the proposed method of laser separation of the homoepitaxial film from the semiconductor substrate consisting of the same semiconductor material as the homoepitaxial film. The scheme illustrates laser separation for the case of selective doping the substrate and homoepitaxial film with fine donor or acceptor impurities when the doping level in the homoepitaxial film exceeds the doping level in the semiconductor substrate. 
           [0029]      FIG. 3  shows a scheme illustrating the proposed method of laser separation of the homoepitaxial film from the semiconductor substrate consisting of the same semiconductor material as the homoepitaxial film. The scheme illustrates laser separation for the case of selective doping the substrate and homoepitaxial film with fine donor or acceptor impurities when the doping level in the semiconductor substrate exceeds the doping level in the homoepitaxial film. 
           [0030]      FIG. 4  shows a scheme illustrating the proposed method of laser separation of the undoped upper layer of the homoepitaxial film from the undoped semiconductor substrate with a laser beam passing through the substrate and absorbed in the lower level of the homoepitaxial film doped with fine donor or acceptor impurities. 
           [0031]      FIG. 5  shows a scheme illustrating the proposed method of laser separation of the undoped upper layer of the homoepitaxial film from the undoped semiconductor substrate with a laser beam passing through the upper undoped layer and absorbed in the lower level of the homoepitaxial film doped with fine donor or acceptor impurities. 
           [0032]      FIG. 6  shows the calculated spectral dependences of the light absorption factor near the residual beams region for semiconductor crystal of gallium nitride at various levels of doping with fine donor impurities. Dependences  601 ,  602  and  603  refer to the doping levels 10 17 , 10 18  and 5.10 19  Cm −3  respectively. 
       
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       [0033]    The present invention will become readily apparent from the following detailed description of exemplary embodiments. It should be noted that the consequent description of these embodiments is only illustrative, but not exhaustive. 
       Example 1 
       [0034]    Separation of homoepitaxial gallium nitride film doped with fine donor impurities from the undoped semiconductor gallium nitride substrate with laser beam passing through the substrate. 
         [0035]      FIG. 2  shows a scheme of laser separation of homoepitaxial gallium nitride film  202 , 50 μm wide from the semiconductor gallium nitride substrate  101 , 200 μm wide. Level of doping with fine silicon donor impurities in the homoepitaxial film  202  is of 5.10 19  cm −3 , and exceeds the background concentration of fine oxygen and silicon donors in the semiconductor substrate  101  equalled 10 17  cm −3 . 
         [0036]    For separating of the homoepitaxial gallium nitride film, CO 2  pulse pumped laser is used operating at the wave length λ=10.6 μm and generating pulses of energy 0.1 J, duration 50 ns and repetition rate 100 Hz. 
         [0037]    Absorption factor of laser radiation with wave length λ=10 μm in the homoepitaxial gallium nitride film  202  doped with fine silicon donor impurities of concentration 5.10 19  cm −3 , equals 4.10 4  Cm −1 , whereas the absorption factor of this radiation in the undoped semiconductor gallium nitride substrate  101  with background concentration of fine oxygen and silicon donors equalled 10 17  cm −3  is 5.10 1  cm −1 . 
         [0038]    The respective spectral dependences of the light absorption factor near the residual beams region which we calculated for the semiconductor gallium nitride crystals with different levels of doping with fine donor impurities are given in  FIG. 6 . The curves  601 ,  602  and  603  refer to the doping levels 10 17 , 10 18  and 510 19  cm 3  respectively. 
         [0039]    Scheme in  FIG. 2  shows that infrared laser beam  203  passes through the substrate  101  and is focused into the spot 1 mm in diameter which provides the energy density of 10 J/cm 2 . Under the action of infrared laser beam  203  of pulse CO 2  laser with wave length λ=10 μm focused into the spot 1 mm in diameter weakly absorbed in the undoped semiconductor gallium nitride substrate  101  and strongly absorbed in the homoepitaxial gallium nitride film  202  doped with fine donor impurities, local heating of the homoepitaxial film  202  takes place in the region  204  defined by crossing of the infrared laser beam  203  with the homoepitaxial interface  205  between the undoped semiconductor substrate  101  and the doped homoepitaxial film  202 . Local heating above temperature 900° C. leads to chemical decomposition of gallium nitride crystal into gaseous nitrogen and liquid gallium in the region  204 . Movement of the laser beam  203  focus with velocity of 10 cm/s in the horizontal plane which is parallel to homoepitaxial interface  205  leads to subsequent decomposition of gallium nitride in the set of regions  204  and weakening of the homoepitaxial interface  205  between the undoped semiconductor substrate  101  and the doped homoepitaxial film  202 . Then when pasting the homoepitaxial film  202  on the temporary metallic ceramic or plastic substrate and applying small mechanical or thermomechanical stress it is possible to separate the homoepitaxial film  202  from the substrate  101 . 
       Example 2 
       [0040]    Separation of undoped homoepitaxial gallium nitride film from semiconductor gallium nitride substrate doped with fine donor impurities, by means of laser beam passing through the homoepitaxial film. 
         [0041]      FIG. 3  shows the scheme of laser separation of undoped homoepitaxial gallium nitride film 100 μm thick from semiconductor gallium nitride substrate 1 mm thick. The background concentration of fine oxygen and silicon donors in the homoepitaxial film  202  is 10 17  cm −3  and is essentially less than the concentration of fine silicon donor impurities in the doped semiconductor substrate  101  equalled 5.10 19  cm −3 . 
         [0042]    For separating of the homoepitaxial gallium nitride film, CO 2  pulse pumped laser is used operating at the wave length λ=10.6 μm and generating pulses of energy 0.1 J, duration 50 ns and repetition rate 100 Hz. Absorption factor of laser radiation with wave length λ=10 μm in the undoped homoepitaxial gallium nitride film  202 , with background concentration of fine oxygen and silicon donors equalled 10 17  cm −3 , is of 5.10 1  cm −1 , whereas the absorption factor of this radiation in the semiconductor gallium nitride substrate  101  doped with fine silicon donor impurities of concentration 5.10 19  cm −3 , equals 4.10 4  cm −1 . The respective spectral dependences of the light absorption factor near the residual beams region which we calculated for the semiconductor gallium nitride crystals with different levels of doping with fine donor impurities are given in  FIG. 6 . The curves  601 ,  602  and  603  refer to the doping levels 10 17 , 1018 and 510 19  cm 3  respectively. 
         [0043]    Scheme in  FIG. 3  shows that the infrared laser beam  203  passes through homoepitaxial film  202  and focused into the spot 1 mm in diameter which provides the energy density of 10 J/cm 2 . 
         [0044]    Under the action of infrared laser beam  203  of pulse CO 2  laser with wave length λ=10.6 μm focused into the spot 1 mm in diameter weakly absorbed in the undoped homoepitaxial gallium nitride film  202  and strongly absorbed in the semiconductor gallium nitride substrate  101  doped with fine donor impurities, local heating of the substrate  101  takes place in the region  204  defined by crossing of the infrared laser beam  203  with the homoepitaxial interface  205  between the doped semiconductor substrate  101  and the undoped homoepitaxial film  202 . Local heating above temperature 900° C. leads to chemical decomposition of gallium nitride crystal into gaseous nitrogen and liquid gallium in the region  204 . Movement of the laser beam  203  focus with velocity of 10 cm/s in the horizontal plane which is parallel to homoepitaxial interface  205  leads to the subsequent decomposition of gallium nitride in the set of regions  204  and to weakening of the homoepitaxial interface  205  between the doped semiconductor substrate  101  and the undoped homoepitaxial film  202 . Then when pasting the homoepitaxial film  202  on the temporary metallic, ceramic or plastic substrate and applying a small mechanical or thermomechanical stress it is possible to separate the homoepitaxial film  202  from the substrate  101 . 
       Example 3 
       [0045]    Separation of the undoped upper layer of the homoepitaxial gallium nitride film from the undoped semiconductor gallium nitride substrate with laser beam passing through the substrate and absorbed in lower layer of homoepitaxial film doped with fine donor impurities.  FIG. 4  shows the scheme of laser separation of the undoped homoepitaxial gallium nitride film  202 , 50 μm thick from the undoped semiconductor gallium nitride substrate  101 , 200 μm thick using the doped lower layer  406  of the homoepitaxial film, 1 μm thick. Level of doping with fine silicon donor impurities in the lower layer  406  of the homoepitaxial gallium nitride film is 5.10 19  cm −3  and exceeds the background concentration of fine silicon and oxygen donor impurities in the semiconductor substrate  101  and the upper layer of the homoepitaxial film  202  equaled 10 17  cm 3 . 
         [0046]    For separating of the homoepitaxial gallium nitride film, CO 2  pulse pumped laser is used operating at the wave length λ=10.6 μm and generating pulses of energy 0.1 J, duration 50 ns and repetition rate 100 Hz. 
         [0047]    Absorption factor of laser radiation with wave length λ=10.6 μm in the lower layer  406  of the homoepitaxial gallium nitride film doped with fine silicon donor impurities with concentration 5.10 19  cm −3  equals 4.10 4  cm −1 , whereas the absorption factor of this laser radiation in the undoped semiconductor gallium nitride substrate  101  and in the undoped upper layer  402  of the homoepitaxial gallium nitride film with background concentrations of fine oxygen and silicon donors of 10 17  cm −3  equals 5.10 1  cm −1 . 
         [0048]    The respective spectral dependences of the light absorption factor near the residual beams region which we calculated for the semiconductor gallium nitride crystals with different levels of doping with fine donor impurities are given in  FIG. 6 . The curves  601 ,  602  and  603  refer to the doping levels 10 17 , 10 18  and 510 19  cm 3  respectively. 
         [0049]    Scheme in  FIG. 4  shows that the laser beam  203  passes through the substrate  101  and is focused into the spot 1 mm in diameter which provides the energy density of 10 J/cm 2 . Under the action of infrared laser beam  203  of pulse CO 2  laser with wave length λ=10.6 μm focused into the spot 1 mm in diameter weakly absorbed in the undoped semiconductor gallium nitride substrate  101  and strongly absorbed in the lower layer  406  of the homoepitaxial gallium nitride film  202  doped with fine donor impurities, local heating of the lower layer  406  of the homoepitaxial film takes place in the region  404 , defined by crossing of the infrared laser beam  203  with the homoepitaxial interface  405  between the undoped semiconductor substrate  101  and the doped lower layer  406  of the homoepitaxial film  202 . Local heating above temperature 900° C. leads to chemical decomposition of gallium nitride crystal into gaseous nitrogen and liquid gallium in the region  404 . Movement of the laser beam  203  focus with velocity of 10 cm/s in the horizontal plane which is parallel to homoepitaxial interface  405  leads to the subsequent decomposition of gallium nitride in the set of regions  404  and to weakening of the homoepitaxial interface  405  between the undoped semiconductor substrate  101  and the doped lower layer  406  of the homoepitaxial film. Then when pasting the undoped upper layer  402  of the homoepitaxial film on the temporary metallic, ceramic or plastic substrate and applying a small mechanical or thermomechanical stress it is possible to separate the undoped upper layer  402  of the homoepitaxial film with non-evaporated part of the lower doped layer  406  from the substrate  101 . 
       Example 4 
       [0050]    Separation of the undoped upper layer of the homoepitaxial gallium nitride film from the undoped semiconductor gallium nitride substrate with laser beam passing through the upper layer of the homoepitaxial film and absorbed in lower layer of homoepitaxial film doped with fine donor impurities. 
         [0051]      FIG. 5  shows a scheme of laser separation of the undoped layer of the homoepitaxial gallium nitride film  202 , 100 μm thick from the undoped semiconductor gallium nitride substrate  101 , 2 μm thick using the doped lower layer  406  of the homoepitaxial gallium nitride film 1 μm thick. Level of doping with fine silicon donor impurities in the lower layer  406  of the homoepitaxial gallium nitride film is 5.10 19  cm 3 , and exceeds background concentration of fine oxygen and silicon donor in the semiconductor substrate  101  and in the upper layer  402  of the homoepitaxial film equaled 10 17  cm 3 . 
         [0052]    For separating of the homoepitaxial gallium nitride film, CO 2  pulse pumped laser is used operating at the wave length λ=10.6 μm and generating pulses of energy 0.1 J, duration 50 ns and repetition rate 100 Hz. 
         [0053]    Absorption factor of laser radiation with wave length λ=10.6 μm in the lower layer  406  of the homoepitaxial gallium nitride film doped with fine silicon donor impurities with concentration 5.10 19  cm −3  equals 4.10 4  cm −1 , whereas the absorption factor of this laser radiation in the undoped semiconductor gallium nitride substrate  101  and in the undoped upper layer  402  of the homoepitaxial gallium nitride film with background concentrations of fine oxygen and silicon donors of 10 17  cm −3  equals 5.10 1  cm −1 . 
         [0054]    The respective spectral dependences of the light absorption factor near the residual beams region which we calculated for the semiconductor gallium nitride crystals with different levels of doping with fine donor impurities are given in  FIG. 6 . The curves  601 ,  602  and  603  refer to the doping levels 10 17 , 10 18  and 5.10 19  cm 3  respectively. 
         [0055]    Scheme in  FIG. 5  shows that the laser beam  203  passes through the upper layer  402  of the homoepitaxial film and is focused into the spot 1 mm in diameter which provides the energy density of 10 J/cm 2 . Under the action of infrared laser beam  203  of pulse CO 2  laser with wave length λ=10.6 μm focused into the spot 1 mm in diameter weakly absorbed in the undoped upper layer  402  of the homoepitaxial gallium nitride film and strongly absorbed in the lower layer  406  of the homoepitaxial gallium nitride film doped with fine donor impurities, local heating of the lower layer  406  of the homoepitaxial gallium nitride film takes place in the region  404  defined by crossing of the infrared laser beam  203  with the interface  505  between the undoped upper layer  402  and the doped lower layer  406  of the homoepitaxial gallium nitride film. Local heating above temperature 900° C. leads to chemical decomposition of gallium nitride crystal into gaseous nitrogen and liquid gallium in the region  404 . Movement of the laser beam  203  focus with velocity of 10 cm/s in the horizontal plane which is parallel to the interface  405  leads to the subsequent decomposition of gallium nitride in the set of regions  404  and to weakening of the interface  405  between the undoped upper layer  402  and the doped lower layer  406  of the homoepitaxial film. Then when pasting the undoped upper layer  402  of the homoepitaxial film on the temporary metallic, ceramic or plastic substrate and applying a small mechanical or thermomechanical stress it is possible to separate the undoped upper layer  402  of the homoepitaxial film from the non-evaporated part of the lower doped layer  406  and from the substrate  101 . 
       Example 5 
       [0056]    Separation of the undoped homoepitaxial silicon carbide 4H-SiC film from the semiconductor silicon carbide 4H-SiC substrate doped with fine donor impurities by means of the laser beam passing through the homoepitaxial film. 
         [0057]      FIG. 3  shows a scheme of laser separation of the undoped homoepitaxial silicon carbide 4H-SiC film  202 , 100 μm thick from the semiconductor silicon carbide 4H-SiC substrate  101 , 400 μm thick. The background concentration of the fine donors in the epitaxial film  202  is less than 10 17  cm −3 , and essentially less than the concentration of the fine nitrogen donor impurities in the doped semiconductor substrate  101  equaled 5.10 19  cm −3 . 
         [0058]    For separating of the homoepitaxial silicon carbide 4H-SiC film, CO pulse pumped laser is used operating at the wave length λ=5.2 μm and generating pulses of energy 0.4 J, duration 50 ns and repetition rate 10 Hz. Absorption factor of laser radiation with wave length λ=5.2 μm in the undoped homoepitaxial silicon carbide 4H-SiC film  202 , with the background concentration of the fine donors less than 10 17  cm −3  is 10 cm −1  (A. M. Hofmeister, K. M. Pitman, A. F. Goncharov, and A. K. Speck The Astrophysical Journal, 696:1502-1516, 2009 May 10), whereas the absorption factor of this radiation in the semiconductor silicon carbide 4H-SiC substrate  101  doped with the fine nitrogen donor impurities of concentration 5.10 19  cm −3  exceeds 10 4  cm −1 . 
         [0059]    Scheme in  FIG. 3  shows that the infrared laser beam  203  passes through the homoepitaxial film  202  and is focused into the spot 1 mm in diameter which provides the energy density of 50 J/cm 2 . 
         [0060]    Under the action of infrared laser beam  203  of pulse CO laser with wave length λ=5.2 μm focused into the spot 1 mm in diameter weakly absorbed in the undoped homoepitaxial silicon carbide 4H-SiC film  202  and strongly absorbed in the semiconductor silicon carbide 4H-SiC substrate  101  doped with the fine donor impurities, local heating of the substrate  101  takes place in the region  204 , defined by crossing of the infrared laser beam  203  with the interface  205  between the doped semiconductor substrate  101  and undoped homoepitaxial film  202 . Local heating to temperature above 2800° C. leads to chemical decomposition of silicon carbide 4H-SiC of the gallium nitride crystal into silicon and carbon in the region  204 . Movement of the laser beam  203  focus with velocity of 2 cm/s in the horizontal plane which is parallel to the interface  205  leads to subsequent decomposition of silicon carbide 4H-SiC in the set of regions  204  and to weakening of the interface  205  between the doped semiconductor substrate  101  and the undoped homoepitaxial film  202 . Then when pasting the epitaxial film  202  on the temporary metallic, ceramic or plastic substrate and applying a small mechanical or thermomechanical stress it is possible to separate the epitaxial film  202  from the substrate  101 . 
       Example 6 
       [0061]    Separation of weakly doped homoepitaxial silicon film from the semiconductor silicon substrate strongly doped with fine boron acceptor impurities using laser beam passing through the homoepitaxial film. 
         [0062]      FIG. 3  shows the scheme of laser separation of weakly doped homoepitaxial silicon film  202 , 50 μm thick from the semiconductor silicon substrate  101 , 700 μm thick. Concentration of the fine boron acceptor impurities equals 10 17  cm 3 , and essentially less than the concentration of the fine boron acceptor impurities in the doped semiconductor substrate  101  equaled 10 19  cm −3 . 
         [0063]    For separating of the homoepitaxial silicon film, CO 2  pulse pumped laser is used operating at the wave length λ=10.6 μm and generating pulses of energy 0.1 J, duration 50 ns and repetition rate 100 Hz. 
         [0064]    Absorption factor of laser radiation with the wave length λ=10.6 μm in the weakly doped homoepitaxial silicon film  202  with concentration of fine acceptors of 10 17  cm 3  is 12 cm −1  (Hara, H. and Y. Nishi, J. Phys. Soc. Jpn 21, 6, 1222, 1966), whereas the absorption factor of this radiation in the semiconductor silicon substrate  101  doped with the fine boron acceptor impurities of concentration 10 19  cm 3  equals 3000 cm −1 . 
         [0065]    Scheme in  FIG. 3  shows that the infrared laser beam  203  passes through the homoepitaxial film  202  and is focused into the spot 0.5 mm in diameter which provides the energy density of 40 J/cm 2 . 
         [0066]    Under the action of infrared laser beam  203  of pulse CO 2  laser with wave length λ=10.6 μm focused into the spot 0.5 mm in diameter weakly absorbed in the undoped homoepitaxial silicon film  202  and strongly absorbed in the semiconductor silicon substrate  101  doped with fine boron acceptor impurities, local heating of the substrate  101  takes place in the region  204 , defined by crossing of the infrared laser beam  203  with the interface  205  between the strongly doped semiconductor substrate  101  and weakly doped homoepitaxial film  202 . Local heating to temperature above 1400° C. leads to partial melting and amorphicity of the silicon crystal in the region  204 . Movement of the laser beam  203  focus with velocity of 20 cm/s in the horizontal plane which is parallel to the interface  205  leads to subsequent melting and amorphycity of silicon crystal in the set of regions  204  and to weakening of the interface  205  between the strongly doped semiconductor substrate  101  and weakly doped homoepitaxial film  202 . Then when pasting the epitaxial film  202  on the temporary metallic, ceramic or plastic substrate and applying a small mechanical or thermomechanical stress it is possible to separate the epitaxial film  202  from the substrate  101 . 
         [0067]    Despite the fact that the present invention was described and illustrated by the examples of the invention embodiments it should be noted that the present invention is in no case limited by the examples given.