WO2014114730A1

WO2014114730A1 - Method for the production of a layer comprising group-iii-element nitride by means of spontaneous delamination

Info

Publication number: WO2014114730A1
Application number: PCT/EP2014/051365
Authority: WO
Inventors: Gilles Nataf; Philippe DE MIERRY; Sébastien CHENOT; Gérard MOLINO
Original assignee: Centre National De La Recherche Scientifique (Cnrs)
Priority date: 2013-01-24
Filing date: 2014-01-24
Publication date: 2014-07-31
Also published as: FR3001331A1

Abstract

The invention relates to a method for the production of a group-III-element nitride-based layer (9), comprising at least the following steps: implanting (10, 50) embrittlement ions in a growth support (6), said implantation step allowing the creation of an embrittled zone (7); depositing (60) a metal or dielectric mask (8) on the growth support (6); and growing (20, 70) the semiconductor layer (9) based on group-III-element nitride on the growth support (6) by means of epitaxial lateral overgrowth (ELO) up to a given thickness sufficient to induce spontaneous separation (80) at the embrittled zone (7).

Description

METHOD FOR MANUFACTURING AN ELEMENT III NITRIDE BASED LAYER BY SPONTANEOUS DECOLUTION

FIELD OF THE INVENTION

The invention relates to a method of producing a semiconductor layer - for example self-supporting - based on elements of columns III and V of the periodic table. Such a layer may be intended for the manufacture of semiconductor structures such as light-emitting diodes (LEDs) or laser diodes (DL).

PRESENTATION OF THE PRIOR ART

Element III nitride semiconductor materials in the periodic table - such as gallium nitride GaN materials - are becoming more and more important in the fields of electronics and optoelectronics, especially for the manufacture of semiconductor components such as light emitting diodes (LEDs) or laser diodes (DL). Current processes for the fabrication of element III nitride semiconductor materials are based on the so-called hetero-epitaxy technique, which consists of growing a crystal - such as a gallium nitride GaN crystal - on a substrate. of different nature - such as a sapphire substrate. However, the heteroepitaxy technique induces many crystal defects in the element III nitride structure, such as dislocations. These crystalline defects limit the performance and service life of element III nitride-based components. These defects arise from the difference in material between the starting substrate (on which is implemented the growth of element III nitride) and the element III nitride layer from which the semiconductor component is manufactured. For example, in the case of the manufacture of a layer of gallium nitride, the starting substrate generally used for growth is sapphire whose crystal lattice parameters (ie mesh parameter) and thermal expansion parameters are very different from those of gallium nitride GaN.

Improvements in manufacturing techniques now make it possible to manufacture III-nitride-based layers having a limited number of crystalline defects (TDD dislocation density <5.10 ⁸ cm- ² , where "TDD" is the acronym for the Anglo-Saxon term "Threading Dislocation Density").

Most current manufacturing processes make it possible to obtain element III nitride layers of orientation (0001) - called polar orientation. In fact, these manufacturing processes use S2A3 orientation (0001) sapphire substrates to grow the element III nitride layers.

Optoelectronic components made on polar orientation III element nitride layers are subjected to polarization effects due to the hexagonal structure of the material. This greatly reduces the efficiency of these optoelectronic components, such as the internal quantum efficiency of a light emitting diode (LED) on a polar orientation gallium nitride layer.

In recent years, many research groups have been interested in other crystalline orientations to completely eliminate (non-polar orientation) or partially (semi-polar orientation) these polarization effects. However, even if the growth of an element III nitride layer on a non-polar or semi-polar orientation Al 2 O 3 sapphire substrate makes it possible to obtain a non-polar oriented element III nitride layer or semi-polar, the crystalline quality of such a non-polar or semi-polar orientation layer is not sufficient to allow the manufacture of optoelectronic components, especially because of the presence of stacking faults.

At present, the only method for obtaining a non-polar or semi-polar orientation III element nitride layer, whose quality is close to that of the orientation III element nitride layers Polar consists of: to grow a very thick layer 1 of polar element III nitride and

- Making a transverse cut of the polar orientation III element nitride layer to obtain:

a slice 2 of non-polar oriented element III nitride or a slice 3 of semipolar orientation III element nitride, and

polishing the non-polar or semi-polar orientation element III nitride wafer 2. This method makes it possible to obtain wafers 2, 3 of element III nitride with a surface area of between 1 and 5 cm ^2. these slices having a quality substantially identical to that of the elemental nitride layers III polar orientation.

However, the small dimensions of these slices 2, 3 do not allow industrialization of this method.

US 7,943,484 discloses a method of separating a semiconductor layer including optoelectronic components. According to US Pat. No. 7,943,484, the existing methods including a step of separating a functionalized layer by implantation have the disadvantage of inducing a degradation of the quality of said layer. To overcome this drawback, US Pat. No. 7,943,484 proposes the implementation of a step of depositing a mask impermeable to implantation ions prior to the implantation step. US 2009/14005 discloses a method of forming a silicon layer, the method comprising a step of making a mask including apertures. A purpose of document US 2009/14005 is to provide a method for making openings of the mask without implementing an etching step. To avoid this etching step, US 2009/14005 proposes the implementation of an ion implantation step and a thermal annealing step to form openings by exfoliation. An object of the present invention is to provide a method of manufacturing nitride layers of element III, in particular of non-polar or semi-polar orientation:

having the same dimensions as the polar orientation III element nitride layers, and

having a quality substantially equivalent to or even greater than that of polar orientation III element nitride layers.

SUMMARY OF THE INVENTION

For this purpose, the invention proposes a method of manufacturing a layer based on element III nitride, for example based on gallium nitride GaN,

remarkable in that the method comprises at least the following steps:

implantation of embrittlement ions in a growth support, the implantation step making it possible to create a weakened zone,

after the implantation step, the deposition of a dielectric or metal mask on the growth support, the deposition step comprising the deposition of a dielectric or metal layer on the entire surface of the growth support and etching of the dielectric or metallic layer so as to form apertures exposing regions of the surface of the growth support,

growth of the element III nitride semiconductor layer on the growth support by lateral epitaxial overgrowth up to a given thickness sufficient to induce spontaneous separation at the weakened zone.

The combination of the steps of implantation and deposition of the mask makes it possible on the one hand to improve the quality of the III nitride layer deposited on the growth support, and on the other hand to weaken the connection between the element III nitride layer and the growth support at the interface therebetween. The growth of the elemental nitride layer III by lateral epitaxial overgrowth (ELO) also makes it possible to improve the quality of the element III nitride layer. Finally, the use of a growth support having a growth surface of non-polar or semi-polar crystalline orientation, allows the growth of a layer of element nitride. III of non-polar or semi-polar orientation of large dimensions.

Within the scope of the present invention, the non-polar or semi-polar crystalline orientation of a material means any crystalline orientation in which the C [0001] axis forms an angle with the normal to the growth surface of the material. material.

It will be understood in the following that when a layer A is mentioned as being on a layer B, it may be directly on the layer B, or may be located above the layer B and separated from said layer B by one or more intermediate layers.

It will also be understood that when a layer A is mentioned as being on a layer B, it may cover the entire surface of the layer B, or a portion of said layer B. a. US 7,943,484 does not describe a method in which implantation is performed over the entire surface of a growth support. In contrast, in US Pat. No. 7,943,484, the implantation of the semiconductor layer takes place on portions of its surface (US Pat. No. 7,943,484, column 2 lines 30-31). This implantation step is followed by a heat treatment step to allow the lateral diffusion of the implantation ions in order to create an embrittlement plane (see US 7,943,484, column 10 lines 13-15).

Furthermore, in US Pat. No. 7,943,484, the implantation step is not implemented before the deposition of an epitaxial lateral growth mask. In contrast, in US Pat. No. 7,943,484, the implantation step is implemented after having made an optoelectronic component in the semiconductor layer to be separated (and therefore after the mask deposition step). An implantation step makes it possible to weaken an area to facilitate the separation of a semiconductor layer. ELO overgrowth improves the quality of the epitaxial crystal. However, as stated in your application, the combination of ELO implantation and overgrowth steps has other advantages; especially : i) the fact that the implantation step is carried out before the overgrowth step makes it possible to improve the quality of the epitaxially grown GaN layer during the ELO overgrowth step, in particular in terms of flatness, (besides its effect known about the ease of separation),

ii) the fact that the ELO overgrowth step is performed after the implantation makes it possible to weaken the interface between the growth support and the GaN layer (in addition to its known effect on the quality of the crystal).

This cumulative effect of these two steps when implemented in this order is neither taught nor suggested in US 7,943,484. On the contrary, US 7,943,484 deters a person skilled in the art to keep the skilled person of the solution according to the invention by teaching him that the implantation step must be performed after the step of overgrowth.

US 2009/14005 does not disclose a method wherein the step of depositing a mask comprises depositing a layer of dielectric material and etching the layer of dielectric material to form apertures.

In contrast, US 2009/14005 proposes to make openings in the mask by an exfoliation technique based on an implantation step followed by a heat treatment step to form exfoliated areas forming growth windows so that no etching step is implemented.

The fact of depositing a layer of dielectric material and etching thereof to form openings makes it possible to control the directions and orientations of the openings to allow the subsequent implementation of the lateral epitaxial growth step.

US 2009/14005 dissuades the skilled person to perform a step of etching teaching him that it is too expensive and difficult to implement.

Those skilled in the art starting from US 2009/14005, would therefore not have been encouraged to perform an etching step to form openings since US 2009/14005 remote from this solution (see US 2009/14005, paragraph [0009]).

Preferred but non-limiting aspects of the process according to the invention are the following:

the method further comprises a step of forming the growth support by depositing a monocrystalline film based on element III nitride on a crystalline substrate of non-polar or semi-polar or polar crystalline orientation, the implantation weakening ions being produced in the monocrystalline film so as to create a weakened zone in the monocrystalline film; the embrittlement ions are chosen from Tungsten, Helium, Neon, Krypton, Chromium, Molybdenum, Iron, Hydrogen or Boron;

the embrittlement ions are tungsten ions;

this makes it possible to obtain a chemical decomposition of the nitride of element III as well as the creation of vacuum in the weakened zone, which contributes to the weakening of the bond between the nitride layer of element III and the growth support,

the implantation step is performed so that the weakened zone is at the interface between the growth support and the mask;

- the step of implanting comprises the embrittlement of ion implantation at an implantation dose of between 10 ¹⁵ and 10 ¹⁷ cm ^"2;

the implantation step comprises the implantation of embrittlement ions at an implantation energy of between 5 keV and 200 keV, preferentially between 75 KeV and 100 KeV;

the spontaneous separation at the level of the weakened zone is implemented during the return to ambient temperature after the step of growth of the element III nitride layer;

this makes it possible to limit the risks of cracking of the nitride layer of element III because of the mechanical stresses it undergoes during cooling,

the crystalline substrate is chosen from sapphire, ZnO, 6H-SiC, LiAlO 2, LiGaO 2, MgAl 2 O 4, Si, GaAs, AlN, GaN, AlGaN;

the crystalline substrate is a sapphire substrate Al2O3;

this makes it possible to improve the quality of the element III nitride layer manufactured thereon, the crystalline substrate is a sapphire substrate A1203 of crystalline orientation chosen from a plane R such that the plane (1-102) or a plane M such as the plane (10-10);

this makes it possible to orient the growth of the element III nitride layer in a non-polar or semi-polar orientation;

the crystalline substrate is a crystalline orientation sapphire substrate A1 2 O 3 selected from a plane A such as the (1 1 -20) plane, or a C (0001) plane;

the step of depositing a mask (dielectric or metallic) comprises depositing a layer (of dielectric or metal) and etching of the layer (dielectric or metal) to form openings, the number and the dimensions of the apertures being provided so that the proportion of monocrystalline film surface covered by the material (dielectric or metallic) is between 20 and 95% of the total surface of the monocrystalline film, and preferably between 50 and 95%;

this makes it possible to improve the quality of the element III nitride layer manufactured on the growth support, in particular by filtering a large number of crossing dislocations originating from the growth support,

the openings are in the form of a strip of width less than 10 micrometers;

this facilitates the implementation of the mask deposition step,

- the report of:

o the spacing between two successive openings, divided by

o the width of an opening,

is between two and ten;

this makes it possible to further improve the quality of the element III nitride layer by filtering the crystalline defects present in the growth support,

the mask is a dielectric mask, the material constituting the dielectric mask being SiNx or SiO2 or TiN;

this makes it possible to improve the quality of the nitride layer of element III by limiting the defects at the edge of the mask; alternatively, the mask may be a metal mask, the material constituting the mask being W, Mo or Cr;

the step of forming a monocrystalline film is carried out by:

o organometallic vapor phase epitaxy (EPVOM), o molecular beam epitaxy (MBE),

o Hydride vapor phase epitaxy (EPVH),

o liquid phase epitaxy (EPL);

the step of forming a monocrystalline film is carried out by organometallic vapor phase epitaxy (EPVOM);

this makes it possible to improve the quality of the element III nitride layer by minimizing, from the beginning of the process, the density of defects present in the growth support prior to the growth of the element III nitride layer;

the support comprises a growth surface of non-polar or semi-polar crystalline orientation.

The invention also relates to a growth support including a growth surface of non-polar or semi-polar or polar crystalline orientation, remarkable in that it comprises a weakened zone by implantation of embrittlement ions.

Preferably, the growth support comprises a monocrystalline film based on element III nitride on a crystalline substrate of non-polar or semi-polar or polar crystalline orientation, the weakened zone extending in the monocrystalline film.

The growth medium may also include a mask (dielectric or metallic) on the growth surface. The invention also relates to a semiconductor layer based on non-polar or semi-polar element III nitride, said layer being able to be obtained by the method described above. In all cases, this layer comprises:

a defect density of between 1 and 5 × ⁹ , and / or

a density of stacking faults of between 1 and ⁵ × 10 ⁵ cm ^-1 , and preferentially

a surface roughness of between 3 nm and 10 nm. BRIEF DESCRIPTION OF THE DRAWINGS

Other advantages and characteristics of the method according to the invention and of the associated product will emerge more clearly from the following description of several variant embodiments, given by way of non-limiting examples, from the appended drawings in which:

- Figure 1 illustrates different orientations (i.e. semi-polar and non-polar) in a gallium nitride crystal;

FIG. 2 illustrates an embodiment of a method for manufacturing a layer based on element III nitride;

FIG. 3 illustrates another embodiment of the method for manufacturing a layer based on element III nitride.

DETAILED DESCRIPTION OF THE INVENTION

The process according to the invention will now be described in more detail with reference to the growth of a GaN gallium nitride layer for producing light-emitting diodes. However, it is obvious to those skilled in the art that the process described hereinafter can be used to grow an element III nitride material other than gallium nitride, which material can be used to produce other semiconductor structures than light-emitting diodes. 1. General principle

FIG. 2 illustrates the steps of a method making it possible to produce a layer of gallium nitride self-supported by deposition of gallium nitride on a growth support.

In general, the filing operation comprises the following steps successively:

a step of implantation of weakening ions in the growth support, at least one step of lateral epitaxial overgrowth (or "ELO"), on the growth support for epitaxializing a layer of non-polar orientation gallium nitride or semi-polar, and

a step of separating the layer of non-polar or semi-polar orientation gallium nitride from its growth support.

The growth support may consist of a single material. For example, the growth support may be a layer of gallium nitride.

Alternatively, the growth support may consist of a stack of layers. For example, the growth support may consist of a stack including a layer of gallium nitride on a layer of aluminum nitride on a sapphire substrate.

1.1. Implantation / separation

The implantation step 10 makes it possible to create a weakened zone at the interface between the growth support and the gallium nitride layer.

The presence of this weakened zone induces the spontaneous separation of the gallium nitride layer from its growth support.

This spontaneous separation is due to the thermal cycle (epitaxy at high temperature followed by cooling at room temperature) that the gallium nitride layer undergoes during the overgrowth step ELO which succeeds the implantation step.

Preferably, the embrittlement ions implanted during the implantation step are tungsten ions.

This allows a local decomposition of the growth medium in the implanted region, especially in the case where it includes a layer of gallium nitride. Indeed, tungsten ions can break down materials such as gallium nitride.

12. Lateral epitaxial overgrowth

The ELO overgrowth step 20 makes it possible to minimize the density of defects contained in the layer of gallium nitride.

The approach used to reduce the dislocation density in the gallium nitride GaN layer consists of:

- initiate a growth mode of gallium nitride GaN per island, then

to promote the coalescence of the islets in order to obtain the layer of gallium nitride GaN,

continue the growth of the gallium nitride GaN layer until the desired thickness is obtained.

The ELO overgrowth step can be based on:

the use of a dielectric or metallic mask including openings in which the islands are formed, as described in document WO99 / 20816;

the use of a layer of dielectric or of metal having no aperture on which islands are spontaneously formed, as described in document EP 1 338 683 (see Example 5). In addition to the advantages mentioned above, the combination of the successive steps of implantation and overgrowth ELO has many advantages.

Indeed, the fact that the implantation step is performed before the ELO overgrowth step improves the quality of the epitaxial gallium nitride layer during the ELO growth step, especially in terms of flatness.

Moreover, the fact that the ELO overgrowth step is performed after implantation makes it possible to weaken the interface between the growth support and the gallium nitride layer. 2. Implementation variant

Referring to Figure 3, there is illustrated an alternative embodiment of a method of manufacturing a non-polar or semi-polar orientation gallium nitride layer from an initial substrate.

The method comprises the following steps:

Deposition 40 of a monocrystalline film 5 on an initial substrate 4 to obtain a growth support 6,

Implantation of embrittlement ions in a growth support 6

Deposit 60 of a dielectric or metallic mask 8 on the growth support 6,

- Growth 70 of a layer of gallium nitride 9 on the growth support 6,

- Separation 80 of the layer of gallium nitride 9.

2.1. Substrate The initial substrate 4 may have a thickness of a few hundred micrometers - generally 350 microns - and be treated by nitriding prior to any gallium nitride deposition step.

The initial substrate 4 may be chosen from Si, AlN, GaN, GaAs, Al 2 O 3 (sapphire), ZnO, SiC, LiAlO 2, LiGaO 2, MgAl 2 O 4, 4H-SiC, or any other type of initial substrate known to those skilled in the art for implement a growth of gallium nitride.

In the embodiment illustrated in FIG. 3, the initial substrate 4 is a sapphire substrate. This improves the optoelectronic quality of the gallium nitride layer made thereon.

The orientation of the nitrides in the gallium nitride layer depends on the crystalline orientation of the initial substrate 4 on which the growth is carried out. The initial substrate 4 may have a crystalline orientation in an R (1-102) plane or in an M (10-10) plane.

In the case of an initial sapphire 4 of crystalline orientation in a plane R, the galliunn nitride grows in the so-called non-polar direction A [1 1 -20]. A non-polar orientation galliunn nitride layer is then obtained.

In the case of an initial sapphire 4 of crystalline orientation in a plane M, a semi-polar galliunn nitride layer [1 1 -22], or (1 -103) is obtained.

The initial substrate 4 may also have other crystalline orientations such as a polar crystalline orientation C (0001), or a crystalline orientation in a plane A (1 1 -20). 2.2. Formation of the monocrystalline film

The method comprises a step of forming a buffer layer on the initial substrate followed by a step of forming a gallium nitride film, the assembly constituting the gallium nitride film 5 shown in FIG. training 40.

This step of forming a gallium nitride film 5 can be carried out by:

- organometallic vapor phase epitaxy (EPVOM),

- molecular beam epitaxy (MBE),

hydride vapor phase epitaxy (EPVH),

- liquid phase epitaxy (EPL).

In the embodiment illustrated in FIG. 3, the formation of the gallium nitride film 5 is carried out by organometallic vapor phase epitaxy (EPVOM). This makes it possible to filter the crystalline defects and thus to minimize, from the beginning of the process, the density of defects that will be present in the layer of gallium nitride epitaxially grown thereafter. The thickness of the gallium nitride film 5 may be between 0.1 and 20 μιτι, preferably between 1 and 2.5 μιτι, and even more preferably of the order of 2 μιτι. In other embodiments, the step of forming a buffer layer may also comprise a step of depositing an aluminum nitride layer, for example in the case of an initial substrate of silicon.

The formation of a buffer layer including a layer of aluminum nitride AIN makes it possible to improve the quality of the subsequently deposited layer of gallium nitride GAN, in particular in the case of an initial substrate of Si which has a coefficient of thermal expansion very different from gallium nitride.

2.3. Implementation step

At the end of the step of forming the gallium nitride film 5 on the initial substrate 4, the growth support 6 is obtained for the growth of the non-polar or semi-polar gallium nitride layer. A 50 implantation of embrittlement ions is implemented in this growth support 6. This implantation 50 allows the creation of a weakened zone 7 at the level of the upper face of the growth support 6.

The implanted ions may be selected from Tungsten, Helium, Neon, Krypton, Chromium, Molybdenum, Iron, Hydrogen, or Boron.

Preferably, the implanted ions are tungsten ions. These have the particularity of decomposing gallium nitride. In terms of dose embrittlement ions when implanted ions are tungsten ions, the ion implanted dose may be between 10 ¹⁵ and 10 ¹⁷ cm-2, and the implantation depth can vary between 10 nm and 100 nm starting from the free surface 61 - called the growth surface - of the growth support 6. Implantation 50 of embrittlement ions can be implemented during a single step or during successive steps. The temperature can be between 4K and 1000K during the implantation step. In all cases, the implantation step 50 is performed so that the weakened zone 7 is at the interface between the growth support 6 and the mask 8.

2.4. Deposition of the mask After implantation, a mask 8 is deposited (step 60) on the growth support 6.

This mask 8 makes it possible on the one hand to weaken the interface between the growth support 6 and the mask 8, and on the other hand to improve the quality of the gallium nitride layer 9 epitaxially grown on it during a subsequent growth step 70 (by filtering the through defects of the growth medium).

The mask may be a mask of dielectric or metallic material. When the mask is a dielectric mask, the material constituting it is preferably of the SiNx or SiO2 or TiN type. This makes it possible to minimize the defects created at the edge of the mask and thus improves the quality of the layer of gallium nitride 9 later epitaxially grown on it. When the mask is a metal mask, the material constituting it is preferably of the Tungsten (W) or Molybdenum (Mo) or Chromium (Cr) type.

The deposit 60 of the mask 8 can be made in the growth chamber of gallium nitride from silane and ammonia directly on the growth support described above. The deposit 60 of the mask 8 may be made by any technique known to those skilled in the art. For example, in one embodiment the step of depositing the mask (dielectric or metallic) comprises:

depositing a layer (of dielectric or metal) on the entire surface of the growth support, and etching the dielectric or metal layer, in particular by photolithography, so as to define openings 81 in the layer (dielectric or metal) exposing micrometric regions of the growth surface of the growth support.

The openings 81 defined during the etching may be one-off or in the form of strips. Advantageously, the point openings may be inscribed in a circle with a radius of less than 10 microns, whereas the openings in the form of a strip have a width of less than 10 micrometers, the length of the strips being limited only by the dimensions of the growth medium .

When the openings 81 are strip-shaped, the spacing between two adjacent openings 81 may be two to ten times greater than the width of the opening. This makes it possible to improve the quality of the layer of gallium nitride epitaxially grown thereon during the subsequent growth stage.

Indeed, the greater the spacing between two adjacent openings, the more the mask can block defects - such as stacking faults and through dislocations - present in the growth medium.

In all cases, the spacing between the openings is intended to allow localized epitaxy of gallium nitride and then the anisotropic and lateral growth of gallium nitride. 2.5. Growth of the gallium nitride layer

Once the mask 8 has been deposited, a growth step 70 of the gallium nitride layer 9 is implemented. The growth step 70 is carried out by ELO. This makes it possible to improve the quality of the gallium nitride GaN layer by reducing the density of dislocations and stacking faults that propagate in a restricted area from the openings of the mask. The ELO growth principle is for example the following. During the epitaxy of the GaN 9 gallium nitride layer, the gallium nitride preferentially grows in the openings of the mask by epitaxy on gallium nitride 5. The growth parameters are adjusted so that the gallium nitride GaN develops laterally. This lateral growth continues, until gradually covering the covered areas of the mask without adhering to it.

This zone of lateral growth above the mask is free of dislocations and stacking faults since it develops in a direction forming an angle with the direction of the defects. Coalescence occurs when the growth fronts of two adjacent crystals meet to form a coalescing joint, vertically above the dielectric bands. The growth of the gallium nitride layer 9 is then continued until a desired thickness of gallium nitride GaN (2D growth) is obtained.

During this growth step 70 of the GaN 9 gallium nitride layer, the implanted embrittlement ions diffuse towards the interface between the surface of the growth support and the mask.

The embrittlement ions induce a decomposition of the gallium nitride deposited on the sapphire substrate and the creation of voids at the interface between the growth support and the mask.

The result is the weakening of gallium nitride in this interface zone.

The spontaneous separation at the weakened zone takes place due to the thermal cycle (high temperature then cooling) that the gallium nitride layer undergoes after the implantation step.

We then obtain:

- the growth medium 6 on the one hand and

the layer of self-supporting gallium nitride 9 on the other hand. This layer of self-supported GaN gallium nitride 9 may then be treated by mechanical or chemical polishing to allow its subsequent use as a GaN _T gallium nitride substrate.

It can then be used for the manufacture of electronic or optoelectronic components such as laser diodes, light-emitting diodes, photodetectors, transistors, etc. Another advantage of the present invention compared to the state of the art is that it allows to reuse the growth support 6 (and more precisely the sapphire substrate 4 in the case of the process illustrated in FIG. 3) several times. after separation of the gallium nitride layer 9, repolishing and optionally resuming growth of the monocrystalline film 5.

Those skilled in the art will have understood that many modifications can be made to the process described above without physically going out of the new teachings presented here. It is therefore obvious that the examples which have just been given are only particular illustrations which are in no way limiting.

Claims

Process for the production of a layer based on element III nitride, for example based on gallium nitride GaN,

characterized in that the method comprises at least the following steps:

implantation (10, 50) of embrittlement ions in a growth support (6), the implantation step making it possible to create a weakened zone (7),

after the implantation step, the deposition (60) of a dielectric or metallic mask (8) on the growth support (6), the deposition step (60) comprising the deposition of a dielectric layer or metal over the entire surface of the growth medium (6) and etching the dielectric or metal layer to form apertures (81) exposing regions of the surface of the growth medium (6),

growing (20, 70) of the III nitride semiconductor layer (9) on the growth support (6) by lateral epitaxial overgrowth (ELO) to a given thickness sufficient to induce spontaneous separation (80) at the weakened zone (7).

The manufacturing method according to claim 1, which further comprises a step of forming the growth support (6) by depositing (40) a monocrystalline film (5) based on element III nitride on a crystalline substrate (4). ) of non-polar or semi-polar or polar polar orientation, the implantation of embrittlement ions being carried out in the monocrystalline film (5) so as to create a weakened zone (7) in the monocrystalline film (5).

Manufacturing method according to one of claims 1 or 2, wherein the embrittlement ions are selected from Tungsten, Helium, Neon, Krypton, Chromium, Molybdenum, Iron, Hydrogen, or Boron.

Manufacturing method according to the preceding claim, wherein the embrittlement ions are tungsten ions.

Method according to any of the preceding claims, wherein the implantation step (10, 50) is performed so that the weakened zone (7) is at the interface between the growth support (6) and the mask (8). The method of any one of the preceding claims, wherein the implantation step (10, 50) comprises implanting embrittlement ions at an implantation dose of between 10 ¹⁵ and 10 ¹⁷ cm ^-2. .

7. Method according to any one of the preceding claims, wherein the implantation step (10, 50) comprises the implantation of embrittlement ions at an implantation energy of between 5 KeV and 200 KeV, preferably between 75 keV and 100 keV.

8. Manufacturing method according to one of the preceding claims, wherein the spontaneous separation (80) at the weakened zone (7) is implemented by a return to ambient temperature after the growth step (20, 70) of the element III nitride layer (9).

9. Manufacturing process according to one of the preceding claims, wherein the crystalline substrate (4) is selected from sapphire, ZnO, 6H-SiC, LJAIO2, LiGaO2,

MgAl 2 O 4, Si, GaAs, AlN, GaN, AlGaN.

10. The manufacturing method according to the preceding claim, wherein the crystalline substrate (4) is a sapphire substrate Al2O3.

1 1. Manufacturing method according to the preceding claim, wherein the crystalline substrate (4) is a crystalline orientation sapphire substrate Al 2 O 3 selected from a plane R such that the plane (1-102) or a plane M such as the plane (10). -10). 12. The manufacturing method according to claim 10, wherein the crystalline substrate (4) is a sapphire substrate A1203 of crystalline orientation selected from a plane A such that the plane (1 1 -20), or a plane C (0001 ).

The manufacturing method as claimed in any one of the preceding claims, wherein the step of depositing (60) a mask (8) comprises depositing a layer and etching of the layer to form openings (81), the number and dimensions of the openings (81) being provided so that the proportion of monocrystalline film surface (5) covered by the dielectric material is between 20 and 95% of the total surface of the monocrystalline film, and preferably between 50 and 95%.

14. The manufacturing method according to the preceding claim, wherein the openings are strip-shaped width less than 10 micrometers. 15. The manufacturing method according to the preceding claim, wherein the ratio of:

- the spacing between two successive openings, divided by

- the width of an opening,

is between two and ten.

16. The manufacturing method according to any one of the preceding claims, wherein the mask is a dielectric mask, the material constituting the dielectric mask being SiNx or SiO2 or TiN. 17. The manufacturing method according to any one of the preceding claims, wherein the step of forming (40) a monocrystalline film (5) is performed by:

- organometallic vapor phase epitaxy (EPVOM),

- molecular beam epitaxy (MBE),

hydride vapor phase epitaxy (EPVH),

- liquid phase epitaxy (EPL).

The manufacturing method according to any of the preceding claims, wherein the step of forming (40) a monocrystalline film (5) is performed by organometallic vapor phase epitaxy (EPVOM).

19. Manufacturing method according to any one of the preceding claims, wherein the support (6) comprises a growth surface (61) of non-polar or semi-polar crystalline orientation.

20. Semiconductor layer (9) based on non-polar or semi-polar or polar element nitride III, characterized in that it can be obtained by the method according to one of claims 1 to 19, said layer being semi-polar or non-polar or polar and having a diameter greater than or equal to 50.8 millimeters.

21. A semiconductor layer (9) according to claim 20 which comprises:

a defect density of between 1 and 5 × ⁹ , and / or

a density of stacking faults of between 1 and ⁵ × 10 ⁵ cm ^-1 .