JP4734786B2 - Gallium nitride compound semiconductor substrate and manufacturing method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a gallium nitride compound semiconductor substrate and a method for manufacturing the same, and particularly to a gallium nitride compound semiconductor substrate having n-type conductivity with reduced threading dislocation density.
[0002]
[Prior art]
Gallium nitride compound semiconductors have a light emission wavelength in the short wavelength region around 400 nm, and therefore can be used as light emission light sources from ultraviolet to green. When used as semiconductor laser diodes, they are several in comparison with conventional red laser diodes. It can be used as a playback device or storage device for double the capacity of media. Furthermore, application to electronic devices such as field effect transistors (FETs) is also expected.
[0003]
In order to produce such a gallium nitride compound semiconductor device, a substrate capable of homoepitaxial growth of bulk single crystal gallium nitride or gallium nitride compound semiconductor is desired. Difficult due to high pressure. Therefore, a gallium nitride compound semiconductor is heteroepitaxially grown on a substrate such as sapphire, silicon carbide, or spinel. A gallium nitride compound semiconductor is grown using this nitride semiconductor substrate as a substrate.
[0004]
If the difference in lattice constant between the substrate and the gallium nitride compound semiconductor stacked on the substrate is large, threading dislocations are generated in the gallium nitride compound semiconductor layer stacked on the substrate. If there are many threading dislocations, the leakage current increases, and the life characteristics of the light emitting element such as a semiconductor laser diode are greatly deteriorated. When a gallium nitride compound semiconductor is grown on a substrate such as sapphire, threading dislocations can be reduced through a buffer layer. For example, JP-A-7-202265 and JP-A-7-165498 report a buffer layer made of ZnO. In addition, although there are AlN and GaN buffer layers, the threading dislocation density is 10⁸Piece / cm²-10¹⁰Piece / cm²Degree. A semiconductor laser diode or a high-power light emitting diode using a gallium nitride compound semiconductor grown on a substrate through such a buffer layer as an element cannot be expected to be continuously oscillated for a long time.
[0005]
  Therefore, an ELO (Epitaxial Lateral Overgrowth) method having an effect of further reducing the threading dislocation density has been reported. This ELO method is a method for reducing dislocations utilizing the lateral growth of a compound semiconductor. For example, a protective film having an opening (window) is formed in, for example, a stripe shape or an island shape on a gallium nitride-based compound semiconductor that is a base layer. Next, a gallium nitride compound semiconductor is grown with the underlying gallium nitride compound semiconductor exposed from the opening of the protective film as a nucleus. A gallium nitride compound semiconductor grown with the underlying layer as a nucleus grows in the vertical direction from the opening and then also grows in the horizontal direction. This lateral growth is continuous growth from the nucleus and grows laterally on the protective film. Thus, threading dislocations grow not only in the vertical direction but also in the horizontal direction, as in the case of gallium nitride compound semiconductors. Therefore, the threading dislocations grown in the lateral direction are concentrated at the junction where the gallium nitride compound semiconductors grown from the adjacent nuclei on the protective film are joined. Therefore, although threading dislocations concentrate on the opening of the protective film and the junction on the protective film, a low dislocation region can be formed on the surface of the lateral growth region excluding these regions.As another method for reducing the threading dislocation density, a first growth layer having a high vertical growth rate and a rough surface is grown, and then the vertical growth rate is lower than that of the first growth layer. Japanese Patent Application Laid-Open No. 2001-168045 discloses a method of growing a growth layer to fill a depression of the first growth layer. Japanese Patent Laid-Open No. 11-1399 discloses a silicon impurity of 10 ¹⁸ -10 ²⁰ cm ^-3 A method for obtaining an n-type gallium nitride semiconductor substrate by adjusting in the above range is described. Such an n-type gallium nitride semiconductor substrate is formed by repeating a gallium nitride growth process and a polishing process.
[0006]
[Problems to be solved by the invention]
However, the ELO method described above has many steps such as pattern formation of a protective film, and it is difficult to efficiently mass-produce. Further, in the ELO method, an opening is provided in the protective film, and the gallium nitride compound semiconductor is grown using the gallium nitride compound semiconductor exposed from the opening as a nucleus. Therefore, a low dislocation region is obtained in the lateral growth region. However, many dislocations are concentrated on the upper portion of the window, which is the opening, and the junction between the gallium nitride compound semiconductors on the protective film. Therefore, it is difficult to provide a substrate having a uniform low dislocation region on the surface, and a ridge stripe must be selectively formed in the low dislocation region. Therefore, the yield is lowered in the photolithography process for forming the ridge stripe on the warped wafer. In addition, a nitride semiconductor substrate obtained by the ELO method has an insulating heterogeneous substrate, and for example, a nitride semiconductor is formed on a sapphire substrate. For this reason, heat dissipation is poor and continuous oscillation at high output for a long time is difficult. In addition, since the sapphire substrate is insulative, an n-type electrode and a p-type electrode must be formed on the surface, and a step of forming a step after the element is grown is necessary. This is also disadvantageous in reducing the chip area as compared with an element in which an electrode is formed on the counter electrode surface. In addition, since the sapphire substrate is not flaky, a dicing process is required for chip separation, resulting in high costs.
[0007]
An object of the present invention is to obtain a low dislocation region uniformly and over a wide area on the surface of a gallium nitride compound semiconductor substrate. Another object of the present invention is to provide a gallium nitride compound semiconductor substrate with improved mass production efficiency by using an n-type low resistance single substrate from which a different substrate is removed.
[0008]
[Means for Solving the Problems]
The gallium nitride compound semiconductor substrate of the present invention has a Si doping concentration of 1 × 10¹⁹/ Cm³The first gallium nitride compound semiconductor layer and the Si concentration lower than that of the first gallium nitride compound semiconductor layer stacked on the first gallium nitride compound semiconductor layer, non-doped, or Si doping concentration is 1 × 10¹⁹/ Cm³A second gallium nitride compound semiconductor layer, which is:The first gallium nitride compound semiconductor layer is grown as an island of gallium nitride compound semiconductor, and the second gallium nitride compound semiconductor layer is formed of an island of the gallium nitride compound semiconductor. Growing and adjacent islands are combined to form threading dislocation density of 1 × 10 ⁸ / Cm ² IsIt is characterized by that.
[0009]
  The method for producing a gallium nitride compound semiconductor substrate according to the present invention is a method for producing a gallium nitride compound semiconductor substrate formed by growing a gallium nitride compound semiconductor layer on a substrate by vapor deposition. Si doping concentration is 1 × 10¹⁹/ Cm³The first step of forming the first gallium nitride compound semiconductor layer, and the first gallium nitride compound semiconductor layer on the first gallium nitride compound semiconductor layer after the first step. The Si concentration is lower than that, non-doped, or Si doping concentration is 1 × 10¹⁹/ Cm³A second step of forming a second gallium nitride compound semiconductor layer,In the first step, the first gallium nitride compound semiconductor layer is an island of gallium nitride compound semiconductor, and in the second step, the second nitridation is performed in the second step. The gallium compound semiconductor layer is formed by growing islands of the gallium nitride compound semiconductor and joining adjacent islands together.It is characterized by that.
[0010]
Thus, the Si doping concentration is 1 × 10¹⁹/ Cm³The Si-rich layer as described above, and the Si doping concentration on the Si-rich layer is non-doped, or 1 × 10¹⁹/ Cm³If the following Si poor layer is grown, dislocation can be reduced. Here, the Si poor layer includes non-doped Si. The reason why dislocation can be reduced will be described below. In the Si-rich layer, Si acts not only as a donor but also as a contaminant on the growth layer. For this reason, the growth of the site where Si or its compound has a high deposition density is delayed. That is, the gallium nitride compound semiconductor grown on the substrate has an in-plane distribution having a growth rate difference. As a result, nuclei are selectively generated in a portion having a high growth rate on the entire surface, and gallium nitride compound semiconductor islands grow on the surface of the gallium nitride compound semiconductor. Next, in the Si poor layer to be grown, the coalescence of the gallium nitride compound semiconductor islands is promoted. This is because crystal grains having a high growth rate grow so as to cover adjacent crystal grains. Here, the island of the gallium nitride compound semiconductor has threading dislocations extending from the growth interface between the substrate and the gallium nitride compound semiconductor. This threading dislocation not only extends in the vertical direction as the island grows, but also extends perpendicularly to the slope that is the growth surface because the surface of the island has a slope shape. Therefore, the threading dislocations bend and the threading dislocations form a loop in the process of island growth and coalescence between adjacent islands. Therefore, threading dislocations extending in a direction other than the longitudinal direction in the first gallium nitride-based compound semiconductor layer can be reduced by forming a loop in the second gallium nitride-based compound semiconductor layer. Further, the first gallium nitride compound semiconductor layer has a Si doping concentration of 5 × 10 5.¹⁹/ Cm³Since the distance between the islands can be formed larger as described above, dislocations can be further reduced when the second gallium nitride compound semiconductor layer is grown. More preferably, the Si doping concentration of the first gallium nitride-based compound semiconductor layer is 1 × 10²⁰/ Cm³That's it. The second gallium nitride compound semiconductor layer has a Si doping concentration of 1 × 10 5.¹⁸/ Cm³The mobility can be improved by the following, and more preferably, the Si doping concentration is 1 × 10 6.¹⁷/ Cm³The following. Specifically, the first gallium nitride compound semiconductor layer is grown on the gallium nitride compound semiconductor substrate via a buffer layer, and threading dislocations are reduced by the second gallium nitride compound semiconductor layer grown thereon. Let With only a buffer layer, threading dislocations are 1 × 10 per unit area⁸Piece / cm²~ 1x10¹⁰Piece / cm²However, with the above structure, the threading dislocation density on the surface of the second gallium nitride-based compound semiconductor layer can be reduced uniformly.⁸Piece / cm²Or less, more preferably 1 × 10⁶Piece / cm²It can be as follows.
[0011]
Furthermore, the Si doping concentration is 1 × 10 6 on the second gallium nitride compound semiconductor layer.¹⁹/ Cm³The third gallium nitride compound semiconductor layer is stacked on the third gallium nitride compound semiconductor layer., The Si concentration is lower than that of the third gallium nitride compound semiconductor layer,Non-doped or Si doping concentration is 1 × 10¹⁹/ Cm³And a fourth gallium nitride compound semiconductor layer which is the following.
[0012]
Thus, if the structure for growing the Si-rich layer and the Si poor layer is repeated twice or more, the threading dislocations form a loop to further reduce the dislocations. In addition, when a thick film is grown by vapor deposition using the halogen transport method, it is possible to form a single substrate consisting only of a gallium nitride compound semiconductor layer from which a dissimilar substrate such as sapphire is removed by grinding or laser irradiation. . Therefore, even a nitride semiconductor substrate grown on an insulator such as a sapphire substrate is removed, and the Si-rich layer is doped with Si at a high concentration to form a low-resistance n-type substrate. Therefore, the electrode can have a counter electrode structure. Here, the step of removing the heterogeneous substrate may be before the growth of the nitride semiconductor element or after the growth of the nitride semiconductor element.
[0013]
In addition, the first and / or second gallium nitride compound semiconductor layer in the gallium nitride compound semiconductor substrate has the general formula In_xAl_yGa_1-xyN (0 ≦ X <1, 0 ≦ Y <1, 0 ≦ X + Y <1). Furthermore, GaN has the effect of reducing pits on the surface after two-stage growth.
[0014]
A silane compound is used as a raw material for Si doping. This silane compound is SiH₄, Si₂H₆, SiHCl₃, SiH₂Cl₂, SiH₃Cl, SiCl₄Is at least one selected from the group consisting of Use of these raw materials is preferable because Si or a compound thereof can be effectively used as a dopant as well as a contaminant.
[0015]
If the first gallium nitride compound semiconductor is directly grown on a heterogeneous substrate such as sapphire, for example, the dislocation density increases due to the difference in lattice constant and thermal expansion coefficient. Therefore, the crystallinity can be further improved by forming the gallium nitride compound semiconductor layer directly on the substrate through the buffer layer which is the base layer. Specifically, In_xAl_yGa_1-xyN (0.ltoreq.X <1, 0.ltoreq.Y <1, 0.ltoreq.X + Y <1), which is formed by low-temperature growth at 700.degree. C. or lower. The gallium nitride compound semiconductor grown only through this underlayer has 10 threading dislocations per unit area.⁸-10¹⁰Piece / cm²It becomes. Therefore, a nitride semiconductor substrate with better crystallinity can be formed by growing the Si rich layer and the Si poor layer on the base layer.
[0016]
  Furthermore, the growth rates of the first gallium nitride compound semiconductor layer and the second gallium nitride compound semiconductor layer can be made substantially the same. In the first step, islands of the first gallium nitride-based compound semiconductor layer can be grown, and in the second step, formation of the second gallium nitride-based compound semiconductor layer can be promoted. Also,Examples of the vapor phase growth method of the gallium nitride compound semiconductor substrate include a vapor phase growth method using a halogen transport method, a metal organic vapor phase growth method, and a molecular beam epitaxy method. The vapor phase growth method based on the halogen transport method is preferable because it can grow a thick film because of its high growth rate. In order to reduce the number of defects in a thin film, another vapor phase growth method such as a metal organic chemical vapor deposition method or a molecular beam epitaxy method in which the lateral growth can be easily controlled may be used.
[0017]
In the method for manufacturing a gallium nitride compound semiconductor substrate, examples of the substrate include sapphire, silicon carbide, spinel, or silicon. These can epitaxially grow a gallium nitride-based compound semiconductor and have heat resistance against the growth temperature. Further, after the gallium nitride compound semiconductor layer is stacked, the substrate can be peeled and removed by grinding, electromagnetic wave irradiation, or the like, whereby a single substrate made of a gallium nitride compound semiconductor can be formed. In the present invention, since the first gallium nitride compound semiconductor layer is an Si-rich layer, the substrate removal surface can be an n-type nitride semiconductor layer. Therefore, it is possible to provide a gallium nitride-based compound semiconductor laser or a light-emitting diode in which electrodes are formed as counter electrodes in a single crystal nitride substrate with reduced threading dislocations and good crystallinity.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
The gallium nitride compound semiconductor substrate according to the embodiment of the present invention is:As shown in FIG.Si doping concentration is 1 × 10¹⁹/ Cm³The first gallium nitride compound semiconductor layer 3 as described above, and the non-doped or Si doping concentration stacked on the first gallium nitride compound semiconductor layer is 1 × 10 6.¹⁹/ Cm³A gallium nitride compound semiconductor substrate comprising a second gallium nitride compound semiconductor layer 4 as described below.
[0019]
Si raw materials are silane compounds, and these silane compounds are SiH.₄, Si₂H₆, SiHCl₃, SiH₂Cl₂, SiH₃Cl, SiCl₄Is at least one selected from the group consisting of
[0020]
The first gallium nitride compound semiconductor and the second gallium nitride compound semiconductor have the general formula In_xAl_yGa_1-xyN (0 ≦ X <1, 0 ≦ Y <1, 0 ≦ X + Y <1).
[0021]
Effect 1
The invention in the present embodiment is performed simultaneously with the growth of the gallium nitride compound semiconductor by Si doping. By performing the two-step growth, the surface is flattened and a gallium nitride compound semiconductor substrate having a low defect region in a wide range is manufactured. be able to. Such flattening is possible due to the natural lateral growth of the crystal. In the gallium nitride compound semiconductor substrate shown in the present embodiment, as a method for reducing dislocations, dislocations are not reduced without embedding facets, but grown while embedding facets to reduce dislocations. As described above, the gallium nitride compound semiconductor substrate can be formed efficiently without the need for planarization by surface polishing or the like.
[0022]
Effect 2
In the present invention, a low-resistance n-type single substrate can be formed by removing the substrate. This is because, in the process of reducing dislocations, Si is continuously doped in the gallium nitride compound semiconductor layer, so that a low-resistance n-type semiconductor layer can be formed. For this reason, it can be set as the structure which formed the electrode in the counter electrode, and it is advantageous to reduction of a chip area. In addition, since there is no heterogeneous substrate such as a sapphire substrate, a dicing process is not required for chip separation, leading to cost reduction. In addition, a single substrate made of a gallium nitride compound semiconductor has a cleavage property, and when a semiconductor laser is formed, the cleavage plane is preferably a resonator mirror. Further, by removing the substrate, the heat dissipation is improved, so that a long life can be expected.
[0023]
Although the manufacturing process of the gallium nitride-type compound semiconductor substrate in one Embodiment of this invention is shown below, it is not limited to this.
[0024]
In the present invention, the substrate may be a single crystal substrate capable of epitaxially growing a nitride semiconductor layer, and the size and thickness of the substrate are not particularly limited. As a specific example of this substrate, sapphire, spinel, silicon carbide (6H, 4H, 3C) on which a C-plane, R-plane, or A-plane is used as a main surface, and preferably a C-axis oriented nitride semiconductor layer is grown. ), Silicon, ZnS, ZnO, SiO₂, GaAs, GaP, diamond, NdGaO₃Other examples include nitride semiconductors. After laminating the gallium nitride compound semiconductor layer, the substrate such as sapphire may be removed. These substrates have a flat surface, but are not particularly limited as long as the gallium nitride compound semiconductor layer can be epitaxially grown. For example, fine roughness is formed by etching or the like on the back surface of the substrate. This roughening can simplify the removal of the substrate. Further, in order to alleviate the warpage, the substrate may have an unevenness, a slope, a staircase shape, etc., and an air bridge structure.
[0025]
Underlayer 2
In as a buffer layer at a low temperature of 800 ° C. or less on the substrate_xAl_yGa_1-xyA first gallium nitride compound semiconductor is grown through N (0 ≦ X <1, 0 ≦ Y <1, 0 ≦ X + Y <1) layers. This is because defects and cracks are suppressed by relaxing the lattice constant mismatch between the substrate and the gallium nitride compound semiconductor. Here, the low temperature is a temperature range of 700 ° C. or lower, preferably 450 ° C. to 650 ° C. If the buffer layer is grown at a temperature within this range, fine nuclei can be formed with good uniformity. If the buffer layer is grown at a temperature of 800 ° C. or higher, uniform nucleation is inhibited, and the crystal is then polycrystallized, so that the crystallinity is lowered. The film thickness is grown from 10 angstroms to 0.5 μm. Furthermore, the underlayer may have a two-layer structure as well as the buffer layer. This is because the second underlayer is grown on the buffer layer (first underlayer) at a high temperature of 950 ° C. or higher to form a flattened underlayer with a mirror surface. Accordingly, the generation of pits in the gallium nitride compound semiconductor grown in the subsequent process can be suppressed. This underlayer can be omitted depending on the substrate.
[0026]
Gallium nitride compound semiconductor
Next, after forming the underlayer 2 on the substrate 1, a first gallium nitride compound semiconductor and a second gallium nitride compound semiconductor are grown. This gallium nitride compound semiconductor has the general formula In_xAl_yGa_1-xyN (0 ≦ X <1, 0 ≦ Y <1, 0 ≦ X + Y <1). However, these may have different compositions. In addition to Si, O, Ge, Sn, S, or the like can be used as a dopant, and a gallium nitride-based compound semiconductor doped with a p-type impurity may be used. Examples of the p-type impurity include Mg, Be, Cr, Mn, Ca, and Zn.
[0027]
The film thickness of the first gallium nitride compound semiconductor layer is 5 μm or more. Preferably, it is 15 μm or more. This is because threading dislocations cannot be bent over a wide range if the thickness of the first gallium nitride compound semiconductor layer is 5 μm or less. By growing the first gallium nitride compound semiconductor layer with this thickness, the direction in which threading dislocations extend after the first gallium nitride compound semiconductor layer is grown can be bent. Next, if the second gallium nitride compound semiconductor layer grown on the first gallium nitride compound semiconductor layer is grown to a thickness of 5 μm or more, preferably 15 μm or more, the second gallium nitride compound semiconductor layer By forming a loop between threading dislocations during growth, threading dislocations can be reduced.
[0028]
As a method of manufacturing a gallium nitride compound semiconductor substrate, a first gallium nitride compound semiconductor, a second gallium nitride compound semiconductor, and a second gallium nitride compound semiconductor are formed on a substrate by a vapor phase epitaxial growth (HVPE) method using a halogen transport method through an underlayer. The method for growing the is shown below. The halide vapor phase epitaxial growth method can grow a thick film in a short time, and is therefore effective for forming a thick film of a nitride semiconductor or forming a single substrate of a nitride semiconductor from which a different kind of substrate is peeled off.
The growth technique, growth process, and growth conditions used in the present invention are shown below.
[0029]
In the present invention, as a vapor phase growth means in the present invention, a halogen transport method in which a halide of a group III element and a compound containing a group V element (a compound containing nitrogen in the present invention) are reacted to perform vapor phase growth on a substrate. The phase growth (halogen-transport vapor phase epitaxy: HVPE) method is mentioned.
[0030]
The halogen gas includes HCl and the like, and is introduced from the halogen gas pipe together with the carrier gas. The halogen gas reacts with a metal such as Ga to generate a halide of a group 3 element, and further, the ammonia gas flowing in from the N source supply pipe reacts to grow a gallium nitride compound semiconductor on the substrate. Let In the HVPE method, in an atmosphere containing a reducing gas (for example, hydrogen), since the entire reaction tube is heated by resistance heating, the silane-based gas that is a dopant gas is decomposed and decomposed before reaching the substrate region, Effective Si doping is difficult. Therefore, by simultaneously introducing the dopant gas and HCl, the decomposition of the silane gas can be suppressed and the doping can be performed efficiently.
[0031]
As a growth condition of the first gallium nitride compound semiconductor, the growth rate may be 5 μm / hour or more. The first gallium nitride compound semiconductor and the second gallium nitride compound semiconductor can have the same growth rate. Therefore, the distortion generated at the interface due to the difference in crystallinity caused by different growth rates can be alleviated. Here, the first gallium nitride compound semiconductor is preferably grown at normal pressure or slightly reduced pressure.
[0032]
Next, after a first gallium nitride compound semiconductor is grown, a second gallium nitride compound semiconductor is grown thereon under the following conditions.
[0033]
The second gallium nitride compound semiconductor is preferably grown at a temperature equal to or higher than that of the first gallium nitride compound semiconductor, and the substrate temperature is set to 900 ° C. or higher. However, if the temperature difference between the first gallium nitride compound semiconductor and the second gallium nitride compound semiconductor is large, it is preferable that the temperature difference is small because residual thermal distortion occurs at the growth layer interface. The thickness of the second gallium nitride compound semiconductor is not particularly limited as long as the uppermost surface is a mirror surface, and may be 15 μm or more. For this reason, the second gallium nitride compound semiconductor can be formed by MOCVD or another vapor deposition method as long as it is a vapor deposition method capable of growing to a thickness of about 15 μm. Furthermore, it is preferable to use the MOCVD method to control the uniformity of crystal nucleus density, orientation characteristics, size, and layer thickness.
[0034]
The gallium nitride compound semiconductor substrate obtained by the above growth method is a gallium nitride compound semiconductor substrate having a flat top surface and a wide range of low-defect portions serving as mirror surfaces. The element formed on the gallium nitride compound semiconductor substrate obtained by the present invention may be a light emitting element, a light receiving element, or an electronic device as long as it uses a gallium nitride compound semiconductor. FIG. 3 shows a semiconductor laser device in which electrodes are formed on the same surface as the light emitting device in the present embodiment. FIG. 4 shows a semiconductor laser device in which electrodes are formed as a counter electrode structure.
[0035]
The gallium nitride compound semiconductor substrate obtained as described above has a threading dislocation density of 1 × 10.⁸/ Cm²Or less, more preferably 1 × 10⁷/ Cm²It is assumed that the second gallium nitride compound semiconductor layer is as follows.
[0036]
【Example】
Examples of the present invention will be described below.
[Example 1]
First, a sapphire substrate having a C-plane as the main surface was used as the substrate 1 and set in an MOCVD apparatus, and thermal cleaning was performed at a temperature of 1050 ° C. for 10 minutes to remove moisture and surface deposits.
[0037]
Next, the underlayer was grown in a two-layer structure. First, the temperature was set to 510 ° C., hydrogen was used as the carrier gas, ammonia and trimethyl gallium were used as the source gas, and a buffer layer made of GaN was grown to a thickness of 200 Å. Next, a flat layer made of GaN and having a film thickness of 3 μm was formed on the buffer layer at a growth temperature of 1050 ° C. In this example, hydrogen was supplied at 20.5 L / min as a carrier gas during growth, ammonia was supplied at 5 L / min, and trimethylgallium was supplied at 25 cc / min as a source gas.
[0038]
After the base layer is grown on the substrate, it is set in an HVPE apparatus in order to grow the first gallium nitride compound semiconductor and the second gallium nitride compound semiconductor.
[0039]
First, Ga metal is prepared as a Ga source in a boat, and GaCl is generated by flowing HCl gas, which is a halogen gas, using nitrogen and / or hydrogen as a carrier gas. Nitrogen and / or hydrogen is used as a carrier gas and an ammonia gas as an N source is flowed to react GaCl and ammonia gas to form GaN in the substrate region. In addition, SiCl using nitrogen and / or hydrogen as a carrier gas_FourThe first gallium nitride compound semiconductor made of Si-doped GaN is grown on the substrate. The temperature of the substrate region was set to 1030 ° C. with an electric furnace. The growth rate of the first gallium nitride compound semiconductor is 50 μm / hour, and the GaCl partial pressure is 1.25 × 10^-3atm, NH₃The partial pressure was 0.375 atm. SiCl₄Partial pressure is 2.87 × 10^-7Atm. The first gallium nitride compound semiconductor was grown to a thickness of 50 μm.
[0040]
Next, a second gallium nitride compound semiconductor was grown on the first gallium nitride compound semiconductor in a vapor phase epitaxial growth apparatus using a halogen transport method. As growth conditions at this time, SiCl₄Partial pressure is 1.0 × 10^-8A second gallium nitride compound semiconductor was grown at a growth rate of 50 μm / hour and a film thickness of 100 μm under the same growth conditions as those of the first gallium nitride compound semiconductor except that it was set to atm.
[0041]
The surface of the second gallium nitride compound semiconductor substrate obtained as described above is flat and mirror-like, and in SIMS analysis, the Si concentration is 2 × 10 2 for the first gallium nitride compound semiconductor layer.¹⁹/ Cm²The second gallium nitride compound semiconductor layer is 2 × 10¹⁸/ Cm²Met. Further, as shown in FIG. 2, according to CL observation, the threading dislocation density is 2 × 10.⁷cm^-2Thus, a gallium nitride compound semiconductor substrate having a low defect can be provided.
[0042]
[Example 2]
A third gallium nitride compound semiconductor layer and a fourth gallium nitride compound semiconductor layer are grown on the gallium nitride compound semiconductor substrate obtained in Example 1 above. The third gallium nitride compound semiconductor layer has the same growth conditions as the first gallium nitride compound semiconductor layer, and the fourth gallium nitride compound semiconductor layer has the same growth conditions as the second gallium nitride compound semiconductor layer. The same shall apply.
[0043]
Since the gallium nitride compound semiconductor substrate obtained as described above becomes a low-dislocation substrate with a thick film grown, it can be a single substrate from which a heterogeneous substrate is removed.
[0044]
[Example 3]
The sapphire substrate is removed by grinding from the gallium nitride compound semiconductor substrate obtained in Example 1, and a single substrate of GaN is obtained. A laser element is formed on this single substrate.
[0045]
(N-type contact layer 102)
First, a single substrate of GaN is set in a reaction vessel of a MOCVD apparatus, TMG, TMA, ammonia, silane gas as impurity gas, and Si-doped Al at 1050 ° C._0.05Ga_0.95An n-type contact layer 102 made of N is grown to a thickness of 4 μm.
[0046]
(Crack prevention layer 103)
Next, using TMG, TMI (trimethylindium), and ammonia, the temperature is set to 900 ° C. and In_0.07Ga_0.93A crack prevention layer 103 made of N is grown to a thickness of 0.15 μm. This crack prevention layer can be omitted.
[0047]
(N-type cladding layer 104)
Next, the temperature is set to 1050 ° C., TMA, TMG, and ammonia are used as source gases, and undoped Al_0.05Ga_0.95An A layer made of N is grown to a thickness of 25 mm, then TMA is stopped, silane gas is used as an impurity gas, and Si is 5 × 10 5.¹⁸/ Cm³A B layer made of doped GaN is grown to a thickness of 25 mm. This operation is repeated 200 times to obtain a laminated structure of the A layer and the B layer, and an n-type cladding layer made of a multilayer film (superlattice structure) having a total film thickness of 1 μm is grown.
[0048]
(N-type guide layer 105)
Next, at the same temperature, an n-type guide layer 105 made of undoped GaN is grown to a thickness of 0.15 μm using TMG and ammonia as source gases. The n-type guide layer 105 may be doped with n-type impurities.
[0049]
(Active layer 106)
Next, the temperature is set to 900 ° C., TMI (trimethylindium), TMG, and ammonia are used as source gas, silane gas is used as impurity gas, and Si is 5 × 10 5.¹⁸/ Cm³Doped In_0.05Ga_0.95The barrier layer made of N is 140 mm thick, the silane gas is stopped, and undoped In_0.13Ga_0.87A well layer made of N is stacked in a thickness of 40 mm in the order of barrier layer / well layer / barrier layer / well layer, and finally, TMI, TMG and ammonia are used as the barrier layer, and undoped In_0.05Ga_0.95Grow N. The active layer 106 has a multiple quantum well structure (MQW) with a total film thickness of 500 mm.
[0050]
(P-type electron confinement layer 107)
Next, at the same temperature as the active layer, TMA, TMG, and ammonia are used as source gases, and Cp is used as an impurity gas.₂Mg (cyclopentadienylmagnesium) is used and Mg is 1 × 10¹⁹/ Cm³Doped Al_0.3Ga_0.7A p-type electron confinement layer 107 made of N is grown to a thickness of 100 mm.
[0051]
(P-type guide layer 108)
Next, the temperature is set to 1050 ° C., TMG and ammonia are used as source gases, and a p-type guide layer 108 made of undoped GaN is grown to a thickness of 0.15 μm. This p-type guide layer may be doped with p-type impurities.
[0052]
(P-type cladding layer 109)
Next, undoped Al at 1050 ° C._0.05Ga_0.95A layer of N is grown to a thickness of 25 mm, then TMA is stopped, Cp₂Using Mg, a B layer made of Mg-doped GaN is grown to a thickness of 25 mm, and this is repeated 90 times to grow a p-type cladding layer 109 made of a superlattice layer having a total thickness of 0.45 μm. The p-type cladding layer has a superlattice structure in which GaN and AlGaN are stacked. By making the p-type cladding layer 109 a superlattice structure, the Al mixed crystal ratio of the entire cladding layer can be increased, so that the refractive index of the cladding layer itself is reduced and the band gap energy is increased. It is very effective in reducing the value.
[0053]
(P-type contact layer 110)
Finally, at 1050 ° C., on the p-type cladding layer 109, TMG, ammonia, Cp₂Mg is used, and Mg is 1 × 10²⁰/ Cm³A p-type contact layer 110 made of doped p-type GaN is grown to a thickness of 150 mm.
After completion of the reaction, the wafer is annealed at 700 ° C. in a nitrogen atmosphere in the reaction vessel to further reduce the resistance of the p-type layer.
[0054]
After annealing, the single substrate made of GaN on which the nitride semiconductor laser elements are stacked is taken out of the reaction vessel, and SiO is deposited on the surface of the uppermost p-type contact layer.₂A protective film made of CF and using RIE (reactive ion etching)₄Etching with gas forms a ridge stripe as a striped waveguide region.
[0055]
Next, after forming the ridge stripe, Zr oxide (mainly ZrO₂Is formed on the p-type guide layer 108 exposed by etching to a thickness of 0.5 μm.
[0056]
A p-type electrode is formed of Ni and Au on the p-type contact layer. Here, the thickness of the p-type electrode is set to 100 mm for Ni and 1300 mm for Au. In addition, an n-type electrode is formed of Ti and Al on the first gallium nitride compound semiconductor layer on the back surface so as to face the p-type electrode. Ti has a thickness of 200 mm and Al has a thickness of 8000 mm. The p-type electrode is formed in stripes on the ridge, and is formed in a direction parallel to and parallel to the n-type electrode similarly formed in stripes. Next, pad electrodes are formed on the p-type electrode and the n-type electrode, respectively. On the p-type electrode, RhO (rhodium oxide) / Pt / Au is formed as a p-type pad electrode with a film thickness of (3000Å-1500Å-6000Å). On the n-type electrode, Ni / Ti / Au is formed as an n-type pad electrode with a film thickness of (1000Å-1000Å-8000Å).
[0057]
After the electrode formation, the n-type electrode side is scribed and cleaved in a bar shape in the direction perpendicular to the ridge stripe, and the cleaved surface is made of SiO.₂And TiO₂A dielectric multilayer film is formed as a resonator mirror. Thereafter, the bar is cut into a laser chip in a direction parallel to the ridge stripe.
[0058]
The laser element obtained as described above has a threshold value of 2.8 kA / cm at room temperature.², A continuous oscillation laser element having an oscillation wavelength of 405 nm at an output of 5 to 60 mW can be obtained. The element lifetime of the obtained laser element is 1000 to 30000 hours.
[0059]
[Example 4]
The sapphire substrate is removed by grinding from the gallium nitride compound semiconductor substrate obtained in Example 1, and a single substrate of GaN is obtained. A laser element is formed in which an n-type electrode and a p-type electrode are formed on the same surface of the single substrate.
[0060]
First, a GaN substrate is set in a reaction vessel of a MOCVD apparatus, and TMG (trimethylgallium), TMA (trimethylaluminum), ammonia is used as a nitride semiconductor at 1050 ° C., and Al is used._0.05Ga_0.95An undoped n-type contact layer 101 made of N is grown to a thickness of 1 μm. This layer functions as a buffer layer between the nitride semiconductor substrate made of GaN and the semiconductor element including the n-type contact layer. However, this undoped n-type contact layer can be omitted.
[0061]
Next, after growing the undoped n-type contact layer, the n-type contact layer 102 / crack prevention layer 103 / n-type clad layer 104 / n-type guide layer 105 / active layer 106 / p-type electrons are further formed under the same conditions as in Example 3. A confinement layer 107 / p-type guide layer 108 / p-type cladding layer 109 / p-type contact layer 110 is grown.
[0062]
Thereafter, a ridge stripe is formed with a ridge width of 1.7 μm. Next, the n-type contact layer is exposed by etching. Then, Zr oxide (mainly ZrO₂Is formed on the p-type guide layer 108 exposed by etching with a film thickness of 0.5 μm or less. Thereafter, a p-type electrode is formed of Ni and Au on the p-type contact layer exposed in a stripe shape. Here, the film thickness of the p-type electrode is Ni (100 Å) and Au (1300 Å). Further, after forming the p-type electrode, an n-type electrode is formed on the exposed n-type contact layer. This n-type electrode is formed of Ti / Al with a film thickness (200Å-8000Å) in parallel on the same plane as the p-type electrode. Further, pad electrodes are formed on the p-type electrode and the n-type electrode, respectively. On the p-type electrode, RhO (rhodium oxide) / Pt / Au is formed as a p-type pad electrode with a film thickness of (3000Å-1500Å-6000Å). On the n-type electrode, Ni / Ti / Au is formed as an n-type pad electrode with a film thickness of (1000Å-1000Å-8000Å).
[0063]
After electrode formation, the back side of the substrate is scribed and cleaved in a bar shape in the direction perpendicular to the ridge stripe.₂And TiO₂A dielectric multilayer film is formed as a resonator mirror. Thereafter, the bar is cut into a laser chip in a direction parallel to the ridge stripe.
[0064]
The laser element obtained as described above has a threshold value of 2.8 kA / cm at room temperature.², A continuous oscillation laser element having an oscillation wavelength of 405 nm at an output of 5 to 60 mW can be obtained. The element lifetime of the obtained laser element is 1000 to 30000 hours.
[0065]
[Example 5]
A laser element is formed on the gallium nitride compound semiconductor substrate with sapphire obtained in Example 1. First, an undoped n-type contact layer 101 is grown on the substrate. The substrate is set in a reaction vessel of an MOCVD apparatus, and TMG (trimethylgallium), TMA (trimethylaluminum), ammonia is used as a nitride semiconductor at 1050 ° C., and Al is used._0.05Ga_0.95An undoped n-type contact layer 101 made of N is grown to a thickness of 1 μm. This layer functions as a buffer layer between the nitride semiconductor substrate made of GaN and the semiconductor element including the n-type contact layer.
[0066]
Next, element formation is performed in the following order under the same conditions as in Example 3.
On the substrate on which the undoped n-type contact layer is grown, n-type contact layer 102 / crack prevention layer 103 / n-type cladding layer 104 / n-type guide layer 105 / active layer 106 / p-type electron confinement layer 107 / p-type guide layer 108 / p-type cladding layer 109 / p-type contact layer 110 are grown in this order.
[0067]
Thereafter, a ridge stripe is formed with a ridge width of 1.7 μm. Next, the n-type contact layer is exposed by etching. Then, Zr oxide (mainly ZrO₂Is formed on the p-type guide layer 108 exposed by etching with a film thickness of 0.5 μm or less. Thereafter, a p-type electrode is formed of Ni and Au on the p-type contact layer exposed in a stripe shape. Here, the film thickness of the p-type electrode is Ni (100 Å) and Au (1300 Å). Further, after forming the p-type electrode, an n-type electrode is formed on the exposed n-type contact layer. This n-type electrode is formed of Ti / Al with a film thickness (200Å-8000Å) in parallel on the same plane as the p-type electrode. Further, pad electrodes are formed on the p-type electrode and the n-type electrode, respectively. On the p-type electrode, RhO (rhodium oxide) / Pt / Au is formed as a p-type pad electrode with a film thickness of (3000Å-1500Å-6000Å). On the n-type electrode, Ni / Ti / Au is formed as an n-type pad electrode with a film thickness of (1000Å-1000Å-8000Å).
[0068]
After electrode formation, the back side of the substrate is diced, cleaved in a bar shape in the direction perpendicular to the ridge stripe, and the cleaved surface is SiO.₂And TiO₂A dielectric multilayer film is formed as a resonator mirror. Thereafter, the bar is cut into a laser chip in a direction parallel to the ridge stripe. The element lifetime of the laser element obtained as described above is 500 to 10,000 hours.
[0069]
[Example 6]
A laser element is formed on the gallium nitride compound semiconductor substrate with sapphire obtained in Example 1. First, an undoped n-type contact layer 101 is grown on the substrate. The substrate is set in a reaction vessel of an MOCVD apparatus, and TMG (trimethylgallium), TMA (trimethylaluminum), ammonia is used as a nitride semiconductor at 1050 ° C., and Al is used._0.05Ga_0.95An undoped n-type contact layer 101 made of N is grown to a thickness of 1 μm. This layer functions as a buffer layer between the nitride semiconductor substrate made of GaN and the semiconductor element including the n-type contact layer.
[0070]
An n-type contact layer 102 / crack prevention layer 103 / n-type cladding layer 104 / n-type guide layer 105 / active layer 106 / p under the same conditions as in Example 3 on the substrate on which the undoped n-type contact layer 101 was grown in the previous period. A semiconductor element is grown in the order of the type electron confinement layer 107 / p type guide layer 108 / p type clad layer 109 / p type contact layer 110.
[0071]
Next, the sapphire substrate is removed by grinding, and a ridge stripe is formed with a ridge width of 1.7 μm. Next, the n-type contact layer is exposed by etching. Then, Zr oxide (mainly ZrO₂Is formed on the p-type guide layer 108 exposed by etching with a film thickness of 0.5 μm or less. Thereafter, a p-type electrode is formed of Ni and Au on the p-type contact layer exposed in a stripe shape. Here, the film thickness of the p-type electrode is Ni (100 Å) and Au (1300 Å). Further, after forming the p-type electrode, an n-type electrode is formed on the exposed n-type contact layer. This n-type electrode is formed of Ti / Al with a film thickness (200Å-8000Å) in parallel on the same plane as the p-type electrode. Further, pad electrodes are formed on the p-type electrode and the n-type electrode, respectively. On the p-type electrode, RhO (rhodium oxide) / Pt / Au is formed as a p-type pad electrode with a film thickness of (3000Å-1500Å-6000Å). On the n-type electrode, Ni / Ti / Au is formed as an n-type pad electrode with a film thickness of (1000Å-1000Å-8000Å).
[0072]
After electrode formation, the back side of the substrate is scribed and cleaved in a bar shape in the direction perpendicular to the ridge stripe.₂And TiO₂A dielectric multilayer film is formed as a resonator mirror. Thereafter, the bar is cut into a laser chip in a direction parallel to the ridge stripe. The element lifetime of the laser element obtained as described above is 1000 to 30000 hours.
[0073]
[Example 7]
In Examples 3 to 6, the n-type electrode is Ti / Al (200 （-8000Å), the p-type electrode is Ni / Au (100Å-1500Å), the n-type pad electrode and the p-type pad electrode are Ni / Ti / Au The laser element is formed under the same conditions except that (1000 と す る -1000Å-8000Å). The lifetime characteristic of the laser element obtained here is 500 to 10,000 hours.
[0074]
[Example 8]
A sapphire substrate having a C surface as a main surface and an orientation flat surface as an A surface is used as the substrate 1, and the substrate 1 is subjected to SiO 2 by CVD.₂A protective film is formed to a thickness of 0.5 μm, a striped photomask is formed, and etching is performed to form a SiO 2 film having a stripe width of 14 μm and a window portion of 6 μm.₂A protective film is formed. The stripe direction of the protective film is a direction perpendicular to the sapphire A plane.
[0075]
Next, by MOCVD, the temperature is 510 ° C., the carrier gas is hydrogen, the source gas is ammonia and TMG (trimethylgallium), and a buffer layer made of gallium nitride is formed on the opening of the protective film to a thickness of 200 Å. Grow in. Thereafter, the temperature is set to 1050 ° C. under a reduced pressure condition by MOCVD, and TMG, ammonia, silane gas, Cp are used as source gases.₂Using Mg (cyclopentadienylmagnesium), a first nitride semiconductor layer made of gallium nitride is grown to a thickness of 10 μm. At this time, the first nitride semiconductor is SiO 2₂The first nitride semiconductor layer is formed so that the cross-sectional shape of the first nitride semiconductor layer is T-shaped, with the opening of the protective film formed as a growth starting point.
[0076]
Next, by isotropic etching, which is dry etching, at a temperature of 120 ° C., oxygen and CF are used as an etching gas.₄Using SiO₂Remove the protective film. Furthermore, from the side and top surfaces of the first nitride semiconductor grown in the lateral direction, the temperature is raised to 1050 ° C. by MOCVD at normal pressure, and TMG, ammonia, silane gas, Cp are used as source gases.₂A second nitride semiconductor layer made of gallium nitride is grown to a thickness of 15 μm using Mg (cyclopentadienyl magnesium).
[0077]
In order to grow the first gallium nitride compound semiconductor and the second gallium nitride compound semiconductor on the substrate obtained as described above, they are set in the HVPE apparatus. Ga metal is prepared as a Ga source in a boat and GaCl is generated by flowing HCl gas, which is a halogen gas, using nitrogen and / or hydrogen as a carrier gas. Nitrogen and / or hydrogen is used as a carrier gas and an ammonia gas as an N source is flowed to react GaCl and ammonia gas to form GaN in the substrate region. In addition, SiCl using nitrogen and / or hydrogen as a carrier gas_FourThe first gallium nitride compound semiconductor made of Si-doped GaN is grown on the substrate. The temperature of the substrate region is set to 1030 ° C. with an electric furnace. The growth rate of the first gallium nitride compound semiconductor is 50 μm / hour, and the GaCl partial pressure is 1.25 × 10^-3atm, NH₃The partial pressure is 0.375 atm. SiCl₄Partial pressure is 2.87 × 10^-7Atm. The first gallium nitride compound semiconductor is grown to a thickness of 50 μm.
[0078]
Next, a second gallium nitride compound semiconductor is grown on the first gallium nitride compound semiconductor in a vapor phase epitaxial growth apparatus using a halogen transport method. As growth conditions at this time, SiCl₄Partial pressure is 1.0 × 10^-8The second gallium nitride compound semiconductor is grown at a growth rate of 50 μm / hour and a film thickness of 100 μm under the same growth conditions as the first gallium nitride compound semiconductor except that it is atm.
[0079]
The surface of the second gallium nitride compound semiconductor substrate obtained as described above is flat and mirror-like, and the threading dislocation density is 1 × 10.⁷cm^-2A low-defect gallium nitride compound semiconductor substrate can be provided as follows.
[0080]
[Example 9]
In the above embodiment, the growth rate of the first gallium nitride compound semiconductor is 50 μm / hour, and the second gallium nitride compound semiconductor is grown at a growth rate of 100 μm / hour, and the gallium nitride compound semiconductor substrate is used under the same conditions. Form. The surface of the second gallium nitride compound semiconductor substrate obtained as described above is flat and mirror-like, and the threading dislocation density is 1 × 10.⁸cm^-2A low-defect gallium nitride compound semiconductor substrate can be provided as follows.
[0081]
【The invention's effect】
As described above, the present invention can provide a low-defect substrate in which crystal defects on the entire surface of the substrate are reduced, not a laterally grown substrate using a protective film or the like. Therefore, the device process can be simplified as compared with the substrate obtained by the ELO method, and a gallium nitride compound semiconductor substrate with improved mass production efficiency can be provided. Further, by removing the substrate, a single substrate of low resistance made of nitride can be obtained, so that heat dissipation is improved and the life characteristics of the nitride semiconductor device can be improved. Furthermore, a counter electrode structure is possible, which is advantageous for reducing the chip area.
[0082]
[Brief description of the drawings]
FIG. 1 is a schematic cross-sectional view of a nitride semiconductor showing an embodiment of the present invention.
FIG. 2 is a CL photograph in Example 1 of the present invention.
FIG. 3 is a schematic cross-sectional view of a nitride semiconductor laser device according to an embodiment of the present invention.
FIG. 4 is a schematic cross-sectional view of a nitride semiconductor laser device according to an embodiment of the present invention.
[Brief description of symbols]
1 ... Board
2 ... Underlayer
3... First gallium nitride compound semiconductor
4. Second gallium nitride compound semiconductor
101: Undoped n-type contact layer
102: n-type contact layer
103 ... Crack prevention layer
104 ... n-type cladding layer
105 ... n-type guide layer
106 ... Active layer
107 ... p-type electron confinement layer
108 ... p-type guide layer
109 ... p-type cladding layer
110 ... p-type contact layer

Claims (10)

In a method of manufacturing a gallium nitride compound semiconductor substrate formed by growing a gallium nitride compound semiconductor layer on a substrate by a vapor deposition method,
Forming a first gallium nitride compound semiconductor layer having a Si doping concentration of 1 × 10 ¹⁹ / cm ³ or more on a substrate;
After the first step, the Si concentration is lower than that of the first gallium nitride compound semiconductor layer on the first gallium nitride compound semiconductor layer, and the doping concentration of non-doped or Si is 1 × 10 ¹⁹ / cm. ^A second step of forming a second gallium nitride compound semiconductor layer that is ³ or less ,
In the first step, the first gallium nitride compound semiconductor layer is an island of gallium nitride compound semiconductor,
In the second step, the second gallium nitride compound semiconductor layer is formed by growing islands of the gallium nitride compound semiconductor and combining adjacent islands with each other . A method for manufacturing a semiconductor substrate. In the first step, fabrication of the gallium nitride-based compound semiconductor substrate according to claim 1 to form the first gallium nitride-based compound semiconductor layer through the base layer made of gallium nitride compound semiconductor on the substrate Method. It said first and / or second gallium nitride-based compound semiconductor layer, according to claim 1 or 2 method for producing a gallium nitride compound semiconductor substrate according to a gallium nitride. After the second step, a third step of forming a third gallium nitride compound semiconductor layer having a Si doping concentration of 1 × 10 ¹⁹ / cm ³ or more, and after the third step, the third nitridation A fourth gallium nitride compound semiconductor having a Si concentration lower than that of the third gallium nitride compound semiconductor layer and non-doped or having a Si doping concentration of 1 × 10 ¹⁹ / cm ³ or less on the gallium compound semiconductor layer. A method for producing a gallium nitride compound semiconductor substrate according to any one of claims 1 to 3 , further comprising a fourth step of forming a layer. The vapor phase growth method method for producing a gallium nitride compound semiconductor substrate according to any one of claims 1 to 4, which is a vapor deposition method using a halogen transport method. The substrate is sapphire, silicon carbide, spinel, or a manufacturing method of a gallium nitride-based compound semiconductor substrate according to any one of claims 1 to 5, wherein the silicon. A first gallium nitride compound semiconductor layer having a Si doping concentration of 1 × 10 ¹⁹ / cm ³ or more;
The Si concentration is lower than that of the first gallium nitride compound semiconductor layer stacked on the first gallium nitride compound semiconductor layer, and the non-doped or Si doping concentration is 1 × 10 ¹⁹ / cm ³ or less. A second gallium nitride compound semiconductor layer,
The first gallium nitride compound semiconductor layer is grown as an island of a gallium nitride compound semiconductor,
The second gallium nitride compound semiconductor layer is formed by growing islands of the gallium nitride compound semiconductor and combining adjacent islands with a threading dislocation density of 1 × 10 ⁸ / cm ² or less. A gallium nitride-based compound semiconductor substrate, wherein: The gallium nitride compound semiconductor substrate according to claim 7 , wherein the threading dislocation density of the second gallium nitride compound semiconductor layer is 1 × 10 ⁶ / cm ² or less. The gallium nitride compound semiconductor substrate according to claim 7 or 8 , wherein the first and / or second gallium nitride compound semiconductor layer is made of gallium nitride. A third gallium nitride compound semiconductor layer having a Si doping concentration of 1 × 10 ¹⁹ / cm ³ or more on a substrate on which the first and second gallium nitride compound semiconductor layers are stacked; A fourth gallium nitride layer stacked on the gallium nitride compound semiconductor layer, having a Si concentration lower than that of the third gallium nitride compound semiconductor layer and having a non-doping or Si doping concentration of 1 × 10 ¹⁹ / cm ³ or less; A gallium nitride compound semiconductor substrate according to any one of claims 7 to 9 , further comprising a compound compound semiconductor layer.

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