The present disclosure relates to a compound semiconductor layer stack, a method of forming the same, and a light-emitting device.
Light-emitting devices and electronic devices using a GaN-based compound semiconductor have been actively developed. Examples of the light-emitting device may include a light emitting diode or a semiconductor laser element that emits red light, a light emitting diode or a semiconductor laser element that emits green light, and a light emitting diode or a semiconductor laser element that emits blue light. In addition, examples of the electronic device may include a power semiconductor having functions of a switching element, a power conversion element, and the like, and examples of a display apparatus may include a display apparatus using the light-emitting device. However, a compound semiconductor layer including the GaN-based compound semiconductor has higher density of dislocation (threading dislocation) generated in the compound semiconductor layer and threading in a stacking direction, as compared with a GaAs-based compound semiconductor or a material system of silicon, or the like. When the threading dislocation extends to a functional layer (e.g., an active layer and a light-emitting layer in the light-emitting device,) inside the device, characteristics of the device are deteriorated. Specifically, the threading dislocation causes generation of a leak current in the electronic device. In addition, the threading dislocation not only causes the generation of the leak current, but also becomes a non-emissive coupling center inside the active layer, thus reducing luminous efficiency, in the light-emitting device. Therefore, in a case where a crystal defect (threading dislocation) has high density, it is difficult to obtain a light-emitting device or an electronic device in which properties of the GaN-based compound semiconductor is sufficiently utilized.
For example, Japanese Unexamined Patent Application Publication No. 2007-214380 discloses, as a technique for reducing the threading dislocation density, a technique of growing a GaN-based compound semiconductor layer on a heterogeneous substrate using an insulating layer mask.
PTL 1: Japanese Unexamined Patent Application Publication No. 2007-214380
Incidentally, the technique disclosed in this patent publication, a top surface of an embedded layer needs to be flat in order to form a device function part on the embedded layer. This leads to issues of not only taking time to form the embedded layer, but also of difficulty in achieving sufficient reduction in the dislocation density.
Therefore, an object of the present disclosure is to provide a compound semiconductor layer stack that configures a base part in a light-emitting device, a method of forming the same, and a light-emitting device including such a compound semiconductor layer stack.
A method of forming a compound semiconductor layer stack of the present disclosure to achieve the above-described object includes:
forming, on a base, a first layer including an island-shaped Alx1Iny1Ga(1-x1-y1)N;
forming, on the first layer, a second layer including Alx2Iny2Ga(1-x2-y2)N; and
forming, on an entire surface including a top of the second layer, a third layer including Alx3Ga(1-x3)N, with the third layer having a top surface that is flat, provided that the following hold true:
0≤x1<1; 0≤x2<1; 0≤x3<1; 0≤y1<1; and 0<y2<1.
A compound semiconductor layer stack of the present disclosure to achieve the above-described object includes:
a first layer being formed on a base and including an island-shaped Alx1Iny1Ga(1-x1-y1)N;
a second layer being formed on the first layer and including Alx2Iny2Ga(1-x2-y2)N; and
a third layer being formed on an entire surface including a top of the second layer, the third layer including Alx3Ga(1-x3)N, with the third layer having a top surface that is flat, provided that the following hold true:
0≤x1<1; 0≤x2<1; 0≤x3<1; 0≤y1≤1; and 0<y2<1.
A light-emitting device of the present disclosure to achieve the above-described object includes:
a compound semiconductor layer stack formed on a base;
a first compound semiconductor layer formed on the compound semiconductor layer stack;
an active layer formed on the first compound semiconductor layer;
a second compound semiconductor layer formed on the active layer;
a second electrode electrically coupled to the second compound semiconductor layer; and
a first electrode electrically coupled to the first compound semiconductor layer,
the compound semiconductor layer stack including
0≤x1<1; 0≤x2<1; 0≤x3<1; 0≤y1<1; and 0<y2<1.
Hereinafter, description is given of the present disclosure on the basis of examples with reference to the accompanying drawings, but the present disclosure is not limited to the examples, and various numerical values and materials in the examples are merely exemplary. It is to be noted that the description is given in the following order.
In a compound semiconductor layer stack of the present disclosure or a compound semiconductor layer stack of the present disclosure that configures a light-emitting device of the present disclosure (hereinafter, these compound semiconductor layer stacks may be collectively referred to as a “compound semiconductor layer stack, or the like of the present disclosure” in some cases), a mode may be employed in which a first layer has a forward tapered sloped surface and a flat top surface. In addition, in a method of forming the compound semiconductor layer stack of the present disclosure, a mode may be employed in which the first layer having the forward tapered sloped surface and the flat top surface is formed. Then, in these cases, a mode may be employed in which a second layer is formed at least on the top surface of the first layer, or a mode may be employed of forming the second layer at least on the top surface of the first layer. Further, a mode may be employed in which the second layer is formed on the top surface and the sloped surface of the first layer, or a mode may be employed of forming the second layer on the top surface and the sloped surface of the first layer. Furthermore, a mode may be employed in which
T2-t>T2-s
is satisfied, where
T2-t denotes a thickness of a part of the second layer formed on the top surface of the first layer, and T2-s denotes a thickness of a part of the second layer formed on the sloped surface of the first layer. In the first layer having the forward tapered sloped surface and the flat top surface, a plane index of the top surface and a plane index of the sloped surface differ from each other. For this reason, as a result of a difference between a growth rate of the second layer on the top surface of the first layer and a growth rate of the second layer on the sloped surface of the first layer, the thickness T2-t of the part of the second layer on the top surface of the first layer and the thickness T2-s of the part of the second layer on the sloped surface of the first layer differ from each other, and T2-t>T2-s holds. When the thickness T2-s≈0 holds,
0.05≤T2-s/T2-t≤0.50
may hold as a relationship between the thickness T2-t and the thickness T2-s, although this is not limitative. The formation of the first layer having the forward tapered sloped surface and the flat top surface is basically based on a growth condition where, for example, a migration length of gallium (Ga) atoms (e.g., a distance by which gallium atoms are able to move on a front surface of a base or the like) is shorter.
Examples of a distance from a front surface of the base to the top surface of the first layer (a thickness T1 of the first layer) may include, but not limited to, 5×10−8 m to 5×10−7 m, and preferably 5×10−8 m to 2×10−7 m. Examples of the thickness T2-t may include, but not limited to, 1×10−9 m to 2×10−7 m, and preferably 1×10−9 m to 1×10−7 m. Examples of the thickness T2-s may include, but not limited to, 1×10−9 m to 1×10−7 m, and preferably 1×10−9 m to 5×10−8 m. Examples of a thickness T3 of a third layer over the top surface of the first layer may include, but not limited to, 5×10−8 m to 5×10−7 m, and preferably 5×10−8 m to 2×10−7 m.
The compound semiconductor layer stack or the like of the present disclosure including the preferred mode described above may have a configuration in which a mask layer is formed on the base, and the first layer is formed on a part of the base not covered with the mask layer. In addition, the method of forming the compound semiconductor layer stack of the present disclosure including the preferred mode described above may have a configuration of forming a mask layer on the base prior to the formation of the first layer, and starting the formation of the first layer from the top of the part of the base not covered with the mask layer. In these cases, the mask layer may be configured by one type of a material selected from the group consisting of SiN, SiO2, and TiO2 The mask layer and the first layer make it possible to obtain a sea-island structure (the first layer corresponds to an island, and the mask layer corresponds to a sea). In other words, the mask layer having an opening is formed on the base, and the base is exposed to a bottom of the opening. A position where the opening is formed is substantially random. In addition, a planar shape of the opening is also substantially random. The formation of the first layer is not started from the top of the mask layer, but is started from an exposed surface of the base. Further, the first layer extends on the mask layer. Examples of a base coverage factor of the mask layer may be 10% to 99%. That is, the opening may be configured to account for 1% to 90% of the front surface of the base. Then, the first layer is started to be formed from the opening in this manner; as a result, it is possible to finally obtain the first layer having the forward tapered sloped surface and the flat top surface. Examples of the thickness of the mask layer may include, but not limited to, 0.1 nm to 5 nm. Forming, as a film, such a very thin mask layer on the base makes it possible to obtain the mask layer having the opening.
Alternatively, the compound semiconductor layer stack or the like of the present disclosure including the preferred mode described above may have a configuration in which the first layer is doped with impurities including Si or Mg, and a doping concentration is 1×1019 cm−3 or more. In addition, the method of forming the compound semiconductor layer stack of the present disclosure including the preferred mode described above may have a configuration of forming the first layer doped with the impurities including Si or Mg on the base; in this case, the doping concentration may be configured to be 1×1019 cm−3 or more. When the first layer is started to be formed on the base, a region with more impurities including Si and a region with less impurities including Si are formed on the front surface of the base. In the region with more impurities, it is difficult for the first layer to be formed similarly to a case where an SiN mask layer is formed, and thus the formation of the first layer is started from the region with less impurities. In addition, when the formation of the first layer is started while being doped with the impurities including Mg, a micro void (vacancy) is generated in the first layer, and the first layer is further grown from the micro void (vacancy) as a starting point. Specifying the doping concentration to be 1×1019 cm−3 or more makes it possible to securely cause these phenomena to occur. Thus, such a mode of forming the first layer makes it possible to finally obtain the first layer having the forward tapered sloped surface and the flat top surface without forming the mask layer.
The compound semiconductor layer stack or the like of the present disclosure including the preferred mode or the configuration described above may further have a configuration in which a multilayer structure (a superlattice structure) of an AlInGaN layer and an AlGaN layer are formed on the third layer. Examples of a composition of the AlInGaN layer may include Alx2Iny2Ga(1-x2-y2)N, and examples of a composition of the AlGaN layer may include Alx3Ga(1-x3)N, although not limited to these compositions. Examples of a thickness of the AlInGaN layer may include 1×10−9 m to 1×10−7 m, and examples of a thickness of the AlGaN layer may include 1×10−9 m to 2×10−7 m.
The compound semiconductor layer stack or the like of the present disclosure including the preferred mode or the configuration described above may further have a configuration in which the base includes an InGaN layer; in this case, an atomic percentage of In atoms in the InGaN layer is preferably 0.5% or more and 30% or less. In addition, the method of forming the compound semiconductor layer stack of the present disclosure including the preferred mode or the structure described above may have a configuration of forming the InGaN layer on the base prior to the formation of the first layer; in this case, an atomic percentage of In atoms in the InGaN layer is preferably 0.5% or more and 30% or less. It is to be noted that the base includes the InGaN layer; specifically, an InGaN template substrate may be used in which a lattice-relaxed InGaN layer (corresponding to the base) is stacked on a sapphire substrate or a silicon substrate, or an InGaN substrate may be used.
In the compound semiconductor layer stack, a method of forming the same, and the light emitting device of the present disclosure, 0≤y1<1 and 0<y2<1 are specified. That is, the first layer may include In, or may not include In.
In a case of y1>0,
0.1≤y1/y2≤0.9
may hold, for example, as a relationship between y1 and y2. When there is too much In components in the first layer, it may be difficult, in some cases, to obtain the first layer having the forward tapered sloped surface and the flat top surface. The In components are preferably high in the second layer, which accelerates growth of the third layer in a direction parallel to the front surface of the base (may be referred to as a “lateral direction” for convenience, in some cases). The third layer does not include In, which accelerates the growth of the third layer in the lateral direction. Thus, as a result of the above, it is possible to obtain the third layer having a flat top surface even when the thickness of the third layer is thin.
In addition, 0≤x1<1, 0≤x2<1, 0≤x3<1, 0≤y1<1, and 0<y2<1 are specified, but it is preferable to satisfy:
0≤x1≤0.20,
0≤x2≤0.40,
0≤x3≤0.40,
0≤y1≤0.20, and
0<y2≤0.20.
It is more preferable to satisfy:
0≤x1≤0.10,
0≤x2≤0.20,
0≤x3≤0.40,
0≤y1≤0.10, and
0<y2≤0.10.
It may be possible to use: a GaN template substrate having a structure in which several μm of a GaN layer (corresponding to the base) is stacked on a sapphire substrate or a silicon substrate with a GaN low-temperature buffer layer interposed therebetween; an AlN template substrate having a structure in which several μm of an AlN layer (corresponding to the base) is stacked on a sapphire substrate or a silicon substrate with an AlN low-temperature buffer layer interposed therebetween; and the InGaN template substrate in which the above-described lattice-relaxed InGaN layer (corresponding to the base) is stacked on a sapphire substrate or a silicon substrate. Alternative examples of the base may include, in addition to the above-described InGaN substrate, a GaN substrate and an AlN substrate, and may further include a GaAs substrate, an SiC substrate, an alumina substrate, a ZnS substrate, a ZnO substrate, an AlN substrate, an LiMgO substrate, an LiGaO2 substrate, an MgAl2O4 substrate, and an InP substrate.
A front surface of a substrate including a Group III-V compound semiconductor may be configured by Group III atoms or may be configured by Group V atoms. The front surface (principal plane) of the base including the Group III-V compound semiconductor (specifically, GaN-based compound semiconductor) may be configured by: a c-plane being a {0001} plane; an a-plane being a {11-20} plane; an m-plane being a {1-100} plane; a {1-102} plane; a {11-2n} plane including a {11-24} plane or a {11-22} plane; a {10-11} plane; a {10-12} plane; a {20-21} plane; a {1-101} plane; a {2-201} plane; or a {11-21} plane. It is to be noted that, for example, notations of a crystal plane exemplified below:
Description is given below of a polar plane, a non-polar plane and a semipolar plane in a nitride semiconductor crystal, with reference to (a) to (e) of
Examples of the light-emitting device of the present disclosure including the various preferred modes and the configurations described above may include a semiconductor optical device such as an edge-emitting semiconductor laser element, an edge-emitting super luminescent diode (SLD), or a semiconductor optical amplifier. The semiconductor optical amplifier does not convert an optical signal into an electric signal, but directly amplifies the optical signal in a state of light; the semiconductor optical amplifier has a laser-structure with a resonator effect being eliminated as much as possible, and amplifies incident light on the basis of an optical gain of the semiconductor optical amplifier. The semiconductor laser element optimizes an optical reflectance at a first edge face (light-exiting edge face) and an optical reflectance at a second edge face (light-reflecting edge face) to thereby configure a resonator, allowing the light to be emitted from the first edge face. Alternatively, an external resonator may be disposed. Meanwhile, the super luminescent diode sets the optical reflectance at the first edge face to a very low value, and sets the optical reflectance at the second edge face to a very high value to allow light generated in an active layer (light-emitting layer) to be reflected by the second edge face and to be emitted from the first edge face, without configuring the resonator. In the semiconductor laser element and the super luminescent diode, a non-reflective coating layer (AR) or a low reflective coating layer is formed on the first edge face, and a high reflective coating layer (HR) is formed on the second edge face. In addition, the semiconductor optical amplifier sets each optical reflectance at the first edge face and the second edge face to a very low value, and amplifies light incident from the second edge face to emit the amplified light from the first edge face, without configuring the resonator. The structure of the light-emitting device of the present disclosure is also applicable to a light-emitting device (semiconductor optical device) such as a surface-emitting laser element (vertical-cavity laser; also referred to as VCSEL) and a light emitting diode (LED). In addition, the configuration and the structure of the light-emitting device of the present disclosure is applicable to a switching element such as a MOSFET or a HEMT, a current amplifying element, a high frequency generating element, or the like.
Examples of a compound semiconductor configuring a first compound semiconductor layer, the active layer (light-emitting layer), and a second compound semiconductor layer may include AlInGaN-based compound semiconductors such as GaN, AlGaN, InGaN, and AlInGaN. Further, these compound semiconductors may contain, when desired, boron (B) atoms, thallium (Tl) atoms, arsenic (As) atoms, phosphorus (P) atoms, or antimony (Sb) atoms. Examples of a formation method (film formation method) of these layers or a formation method (film formation method) of the first layer, the second layer and the third layer may include a metalorganic chemical vapor deposition method (MOCVD method, MOVPE method), a molecular beam epitaxy method (MBE method), a metalorganic molecular beam epitaxy method (MOMBE method), a hydride vapor-phase epitaxial method (HVPE method) in which a halogen contributes to transportation or reaction, a plasma-assisted physical vapor deposition method (PPD method), an atomic layer deposition method (ALD method, atomic layer deposition method), and a sputtering method. Here, examples of an organic gallium source gas in the MOCVD method may include a trimethylgallium (TMG) gas and a triethylgallium (TEG) gas, and examples of a nitrogen source gas include an ammonia gas and a hydrazine gas. In addition, in a case where aluminum (Al) or indium (In) is contained as a constituent atom of an AlInGaN-based compound semiconductor layer, a trimethylaluminum (TMA) gas may be used as an Al source, and a trimethylindium (TMI) gas may be used as an In source. Further, a monosilane gas (SiH4 gas) may be used as an Si source, and a cyclopentadienyl magnesium gas, methylcyclopentadienyl magnesium or biscyclopentadienyl magnesium (Cp2Mg) may be used as an Mg source. In a case where a stripe structure is formed from a stacked emitter structure including the first compound semiconductor layer, the active layer, and the second compound semiconductor layer, examples of an etching method of the stacked emitter structure to form the stripe structure may include a combination of a lithography technique and a wet etching technique and a combination of a lithography technique and a dry etching technique. The stacked emitter structure is formed on the compound semiconductor layer stack, and has a structure in which the first compound semiconductor layer, the active layer, and the second compound semiconductor layer are stacked from side of the compound semiconductor layer stack, as described above.
The active layer (light-emitting layer) desirably has a quantum well structure. Specifically, the active layer may have a single quantum well structure (SQW structure), or may have a multiple quantum well structure (MQW structure). The active layer having the quantum well structure has a structure in which at least one layer of a well layer and at least one layer of a barrier layer are stacked; however, examples of a combination of (a compound semiconductor configuring the well layer and a compound semiconductor configuring the barrier layer) may include (InGaN, GaN), (InGaN, AlInGaN), (InGaN, InGaN) [provided that a composition of InGaN configuring the well layer and a composition of InGaN configuring the barrier layer differ from each other]. Further, the barrier layer may be configured by a group of layers having a plurality of compositions.
In order to impart an n-type electrically-conductive type to the first compound semiconductor layer and to impart a p-type electrically-conductive type to the second compound semiconductor layer, impurities may be introduced into each of the first compound semiconductor layer and the second compound semiconductor layer. Examples of n-type impurities to be added to the compound semiconductor layer may include silicon (Si), sulfur (S), selenium (Se), germanium (Ge), tellurium (Te), tin (Sn), carbon (C), titanium (Ti), oxygen (O) and palladium (Pd), and examples of p-type impurities may include zinc (Zn), magnesium (Mg), carbon (C), beryllium (Be), cadmium (Cd), calcium (Ca), and barium (Ba).
The first compound semiconductor layer is electrically coupled to a first electrode, and the second compound semiconductor layer is electrically coupled to a second electrode. The second electrode may be in a form of a monolayer configuration or a multilayer configuration (e.g., a palladium layer/platinum layer stack structure in which a palladium layer is in contact with the second compound semiconductor layer, or a palladium layer/nickel layer stack structure in which the palladium layer is in contact with the second compound semiconductor layer) including at least one type of a metal (including an alloy) selected from the group consisting of, for example, palladium (Pd), nickel (Ni), platinum (Pt), gold (Au), cobalt (Co), and rhodium (Rh), or may be in a form of a transparent electrically-conductive material such as ITO. The first electrode desirably has a monolayer structure or a multilayer structure including at least one type of a metal (including an alloy) selected from the group consisting of, for example, gold (Au), silver (Ag), palladium (Pd), platinum (Pt), nickel (Ni), aluminum (Al), titanium (Ti), tungsten (W), vanadium (V), chromium (Cr), copper (Cu), zinc (Zn), tin (Sn), and indium (In), and examples thereof may include Ti/Au, Ti/Al, Ti/Pt/Au, Ti/Al/Au, Ti/Pt/Au, Ni/Au, Ni/Au/Pt, Ni/Pt, Pd/Pt, and Ag/Pd. It is to be noted that the former layer of the virgule “/” in the multilayer configuration is positioned closer to side of the active layer. The same applies to the following description. The first electrode is electrically coupled to the first compound semiconductor layer; however, a mode in which the first electrode is formed on the first compound semiconductor layer and a mode in which the first electrode is coupled to the first compound semiconductor layer via an electrically-conductive material layer or the compound semiconductor layer stack may be included. The first electrode and the second electrode may be formed, as films, by, for example, a PVD method such as a vacuum vapor deposition method or a sputtering method.
A pad electrode may be provided on the first electrode or the second electrode for electrical coupling to an external electrode or a circuit. The pad electrode desirably has a monolayer configuration or a multilayer configuration including at least one type of a metal (including an alloy) selected from the group consisting of Ti (titanium), Aluminum (Al), Pt (platinum), Au (gold), Ni (nickel), and Pd (palladium). Alternatively, the pad electrode may also have a multilayer configuration as exemplified in the multilayer configuration of Ti/Pt/Au, the multilayer configuration of Ti/Au, a multilayer configuration of Ti/Pd/Au, the multilayer configuration of Ti/Pd/Au, a multilayer configuration of Ti/Ni/Au, and a multilayer configuration of Ti/Ni/Au/Cr/Au.
In addition, in a case where the second electrode is formed on or over the second compound semiconductor layer having a p-type electrically-conductive type, a transparent electrically-conductive material layer may be formed between the second electrode and the second compound semiconductor layer. Examples of the transparent electrically-conductive material configuring the transparent electrically-conductive material layer may include indium-tin oxide (including ITO, Indium Tin Oxide, Sn-doped In2O3, crystalline ITO and amorphous ITO), indium-zinc oxide (IZO, Indium Zinc Oxide), IFO (F-doped In2O3), tin oxide (SnO2), ATO (Sb-doped SnO2), FTO (F-doped SnO2), zinc oxide (including ZnO, Al-doped ZnO, and B-doped ZnO), and TNO (Nb-doped TiO2).
The light-emitting device of the present disclosure is applicable, for example, to a display apparatus. That is, examples of such a display apparatus may include a projector apparatus, an image display apparatus and a monitor apparatus each provided with the light-emitting device of the present disclosure as a light source, and a head-mounted display (HMD), a head-up display (HUD) and various types of lighting provided with the light-emitting device of the present disclosure as a light source. In addition, the light-emitting device of the present disclosure may be used as a light source of a microscope. However, the light-emitting device of the present disclosure is not limited to these fields.
Example 1 relates to the compound semiconductor layer stack and the method of forming the same of the present disclosure, and to the light-emitting device of the present disclosure.
A compound semiconductor layer stack 10 of Example 1 includes:
a first layer 11 being formed on a base 14 and including an island-shaped Alx1Iny1Ga(1-x1-y1)N;
a second layer 12 being formed on the first layer 11 and including Alx2Iny2Ga(1-x2-y2)N; and
a third layer 13 being formed on an entire surface including a top of the second layer 12, the third layer 13 including Alx3Ga(1-x3)N, with the third layer 13 having a top surface 13A that is flat, provided that the following hold true: 0≤x1<1; 0≤x2<1; 0≤x3<1; 0≤y1<1; and 0<y2<1.
The light-emitting device of Example 1 includes, for example, an edge-emitting semiconductor laser element, and includes
a compound semiconductor layer stack formed on the base 14,
a first compound semiconductor layer 21 formed on the compound semiconductor layer stack 10,
an active layer 23 formed on the first compound semiconductor layer 21,
a second compound semiconductor layer 22 formed on the active layer 23,
a second electrode 26 electrically coupled to the second compound semiconductor layer 22, and
a first electrode 25 electrically coupled to the first compound semiconductor layer 21, and the compound semiconductor layer stack includes the compound semiconductor layer stack 10 of Example 1.
The semiconductor laser element of Example 1 emits light having a wavelength of, but not limited to, 440 nm or more and 600 nm or less, and preferably 495 nm or more and 570 nm or less.
In addition, the first layer 11 has a forward tapered sloped surface 11B and a flat top surface 11A. Here, the second layer 12 is formed at least on the top surface 11A of the first layer 11. In the illustrated example, the second layer 12 is formed on the top surface 11A and the sloped surface 11B of the first layer 11; however, in some cases, the second layer 12 is formed only on the top surface 11A of the first layer 11. When T2-t denotes a thickness of a part of the second layer 12 formed on the top surface 11A of the first layer 11, and T2-s denotes a thickness of a part of the second layer 12 formed on the sloped surface 11B of the first layer 11,
T2-t>T2-s
is satisfied.
The top surface 11A of the first layer 11 is configured by a (0001) plane, and the sloped surface of 11B is configured by a (11-22) plane. For this reason, a growth rate of the second layer 12 on the top surface 11A of the first layer 11 and a growth rate of the second layer 12 on the sloped surface 11B of the first layer 11 differ from each other. Specifically, the growth rate of the second layer 12 on the sloped surface 11B of the first layer 11 is slower than the growth rate of the second layer 12 on the top surface 11A of the first layer 11. As a result, the thickness T2-t of the part of the second layer 12 on the top surface 11A of the first layer 11 and the thickness T2-s of the part of the second layer 12 on the sloped surface 11B of the first layer 11 differ from each other, and T2-t>T2-s holds. When the thickness T2-s≠0 holds,
0.05≤T2-s/T2-t≤0.50
may hold as a relationship between the thickness T2-t and the thickness T2-s, although this is not limitative.
Examples of a distance from a front surface of the base 14 to the top surface 11A of the first layer 11 (thickness T1 of the first layer 11 in
Further, in Example 1, a mask layer 16 is formed on the base 14, and the first layer 11 is formed on a part of the base 14 not covered with the mask layer 16. The mask layer 16 includes SiN, for example. Examples of a thickness of the mask layer 16 may include, but not limited to, 0.1 nm to 5 nm. The mask layer 16 has an opening 17.
In Example 1,
0.1≤y1/y2≤0.9
is satisfied. Specifically, the following were set:
A GaN template substrate was used having a structure in which several μm of a GaN layer (collectively denoted by a reference numeral 15 in the drawing) is stacked on a sapphire substrate or a silicon substrate (collectively denoted by a reference numeral 14A in the drawing) with a GaN low temperature buffer layer interposed therebetween. The GaN layer 15 exposed to the opening 17 corresponds to the base 14, and the front surface (exposed surface) of the base 14 is configured by the (0001) plane. In some cases, the GaN substrate may also be used as the base 14
The first compound semiconductor layer 21, the active layer (light-emitting layer) 23 and the second compound semiconductor layer 22 that configure the stacked emitter structure were set as exemplified in Table 2 below.
Hereinafter, description is given of a method of forming the compound semiconductor layer stack of Example 1 with reference to
First, a GaN template substrate is prepared which has a structure in which several μm of the GaN layer 15 is stacked on a sapphire substrate or a silicon substrate 14A with a GaN low-temperature buffer layer interposed therebetween. Then, the mask layer 16 is formed on the base 14 on the basis of the MOCVD method (see
Next, the first layer 11 including an island-shaped Alx1Iny1Ga(1-x1-y1)N is formed on the base 14 on the basis of the MOCVD method. Specifically, the first layer 11 of a three-dimensional structure having the forward tapered sloped surface 11B and the flat top surface 11A is formed. The first layer 11 is formed on the part of the base 14 not covered with the mask layer 16. That is, the formation of the first layer 11 is started from the top of the base 14 exposed to a bottom of the opening 17 of the mask layer 16. As the formation of the first layer 11 proceeds, the first layer 11 extends on the mask layer 16. Then, the first layer 11 of a three-dimensional structure having the forward tapered sloped surface 11B and the flat top surface 11A is finally formed (see
Then, the second layer 12 including Alx2Iny2Ga(1-x2-y2)N is formed at least on the first layer 11 on the basis of the MOCVD method (see
Subsequently, the third layer 13 including Alx3Ga(1-x3)N is formed on an entire surface including a top of the second layer 12 on the basis of the MOCVD method (see
For example, the currently available structure including the first layer of AlGaN and the third layer of GaN formed on the first layer without forming the second layer requires formation of the third layer having a film thickness of several μm to obtain such flatness as to obtain atomic steps. Meanwhile, in Example 1, even when the thickness T3 of the third layer 13 is about 200 nm to 300 nm, it is possible to obtain such flatness as to obtain the atomic steps in the third layer 13, and it is possible to reduce the threading dislocation density by one to two orders of magnitude as compared with the currently available structure.
Thereafter, the first compound semiconductor layer 21, the active layer 23, and the second compound semiconductor layer 22 are sequentially formed on the third layer 13 on the basis of the MOCVD method. Next, an etching mask is formed on the second compound semiconductor layer 22, and the etching mask is used to etch the second compound semiconductor layer 22 and the active layer 23 in the thickness direction, for example, on the basis of the RIE method. Further, the first compound semiconductor layer 21 is partially etched in the thickness direction to thereby form a stripe structure 20, and thereafter the etching mask is removed. Subsequently, an insulating layer 24 is formed all over, and a part of the insulating layer 24 positioned on a top surface of the second compound semiconductor layer 22 is removed. Then, the second electrode 26 is formed on the exposed second compound semiconductor layer 22. In addition, a portion of the first compound semiconductor layer 21 is exposed, and the first electrode 25 is formed on the exposed portion. Further, pad electrodes 27 and 28 are formed on the first electrode 25 and the second electrode 26, respectively.
Subsequently, cleaving the compound semiconductor layer stack and the stacked emitter structure allows for formation of a first edge face and a second edge face. Then, a coating layer of each of the first edge face and the second edge face is formed. Thereafter, a terminal or the like is formed on the basis of a well-known method to couple an electrode to an external circuit or the like, and packaging or sealing is performed to thereby completing the light-emitting device of Example 1.
As has been described above, in the compound semiconductor layer stack and the method of forming the same of Example 1 as well as in the light-emitting device (including an electronic device) of the present disclosure, the compound semiconductor layer stack has the structure of including the first layer of a three-dimensional structure, the second layer formed on the first layer and having a composition different from that of the first layer, and the third layer formed on the second layer and having a composition different from that of the second layer, thus making it possible to obtain the third layer having a flat top surface despite thin thickness. Accordingly, it is possible to considerably reduce time required to form the compound semiconductor layer stack. In addition, in the currently available technique, forming compound semiconductor layers having different lattice constants on the compound semiconductor layer results in higher threading dislocation density, whereas, in Example 1, as a result of the acceleration of the growth of the third layer growth in the lateral direction on the second layer, the dislocation annihilation is more likely to occur, thus making it possible to achieve a reduction in the threading dislocation density. Then, consequently, the light-emitting device (including an electronic device) makes it possible to achieve a reduction in the leak current and an improvement in reliability. Further, the light-emitting element makes it possible to achieve an improvement in luminous efficiency, in addition to the reduction in the leak current and the improvement in the reliability.
Example 2 is a modification example of Example 1. As
Except for the points described above, configurations and structures of the compound semiconductor layer stack and the light-emitting device of Example 2 may be similar to the configurations and the structures of the compound semiconductor layer stack and the light-emitting device of Example 1, and thus detailed descriptions thereof are omitted.
Example 3 is a modification example of Example 1 to Example 2. As
Except for the points described above, configurations and structures of the compound semiconductor layer stack and the light-emitting device of Example 3 may be similar to the configurations and the structures of the compound semiconductor layer stacks and the light-emitting devices of Example 1 to Example 2, and thus detailed descriptions thereof are omitted.
It is to be noted that appropriate selection of a growth temperature as well as a growth pressure, a composition ratio between a gas source containing group III atoms and a gas source containing group V atoms to be used for the growth of the first layer 11′, and a growth rate also makes it possible to obtain the first layer 11′ having the forward tapered sloped surface 11B and the flat top surface 11A. Specifically, the growth temperature may be set to a low temperature equal to or less than 1000° C., and the growth pressure may set high. That is, for example, the growth temperature of the first layer 11′ is first set to 700° C. or less to grow the first layer 11′ by several nm to several tens of nm, and then the growth temperature of the first layer 11′ is set to 700° C. or more, thereby making it possible to obtain the first layer 11′ having the forward tapered sloped surface 11B and the flat top surface 11A.
Example 4 is a modification example of Example 1 to Example 3. As
Except for the points described above, configurations and structures of the compound semiconductor layer stack and the light-emitting device of Example 4 may be similar to the configurations and the structures of the compound semiconductor layer stacks and the light-emitting devices of Example 1 to Example 3, and thus detailed descriptions thereof are omitted.
Although the description has been given hereinabove of the present disclosure on the basis of preferred examples, the present disclosure is not limited to these examples. The configurations and the structures of the compound semiconductor layer stacks and the devices and the method of forming the compound semiconductor layer stack described in the examples are merely illustrative, and may be modified where appropriate. The light-emitting device has been described solely as a semiconductor-laser element; however, alternatively, the light-emitting diode (LED), the super luminescent diode (SLD), or the semiconductor optical amplifier may also be employed as the light-emitting device. It is to be noted that configurations and structurers of the SLD and the semiconductor optical amplifier may be substantially the same as the configurations and the structurers of the light-emitting devices (semiconductor optical devices) described in Example 1 to Example 4, except for a difference in the optical reflectances in the light-exiting edge face and the light-reflecting edge face.
In the examples, the stripe structure 20 has a linearly extending shape, but is not limited thereto; the stripe structure 20 may not only extend at a constant width, but also have a tapered shape or a flared shape. Specifically, for example, there may be a configuration of being spread gently in a tapered manner, monotonically, from the light-exiting edge face toward the light-reflecting edge face, or a configuration of being first spread to exceed the maximum width and then being narrowed, from the light-exiting edge face toward the light-reflecting edge face.
It is to be noted that the present disclosure may also have the following configurations.
A method of forming a compound semiconductor layer stack, the method including:
forming, on a base, a first layer including an island-shaped Alx1Iny1Ga(1-x1-y1)N;
forming, on the first layer, a second layer including Alx2Iny2Ga(1-2x-y2)N; and
forming, on an entire surface including a top of the second layer, a third layer including Alx3Ga(1-x3)N, the third layer having a top surface that is flat,
provided that the following hold true:
0≤x1<1; 0≤x2<1; 0≤x3<1; 0≤y1<1; and 0<y2<1.
The method of forming the compound semiconductor layer stack according to [A01], in which the first layer having a forward tapered sloped surface and a flat top surface is formed.
The method of forming the compound semiconductor layer stack according to [A02], in which the second layer is formed at least on the top surface of the first layer.
The method of forming the compound semiconductor layer stack according to [A03], in which the second layer is formed on the top surface and the sloped surface of the first layer.
The method of forming the compound semiconductor layer stack according to [A04], in which
T2-t>T2-s
is satisfied, where
T2-t denotes a thickness of a part of the second layer formed on the top surface of the first layer, and
T2-s denotes a thickness of a part of the second layer formed on the sloped surface of the first layer.
The method of forming the compound semiconductor layer stack according to any one of [A01] to [A05], in which
a mask layer is formed on the base, and
the formation of the first layer is started from a top of a part of the base not covered with the mask layer.
The method of forming the compound semiconductor layer stack according to [A06], in which the mask layer includes one type of a material selected from the group consisting of SiN, SiO2, and TiO2.
The method of forming the compound semiconductor layer stack according to any one of [A01] to [A05], in which
the first layer doped with impurities including Si or Mg is formed, and
a doping concentration is 1×1019 cm−3 or more.
The method of forming the compound semiconductor layer stack according to any one of [A01] to [A08], in which a multilayer structure of an AlInGaN layer and an AlGaN layer is formed on the third layer.
The method of forming the compound semiconductor layer stack according to any one of [A01] to [A09], in which
the base forms an InGaN layer, and
the first layer is formed on the InGaN layer.
The method of forming the compound semiconductor layer stack according to [A10], in which an atomic percentage of In atoms in the InGaN layer is 0.5% or more and 30% or less.
The method of forming the compound semiconductor layer stack according to any one of [A01] to [A09], in which
an InGaN layer is formed on the base,
the mask layer is formed on the InGaN layer, and
the formation of the first layer is started from the top of the part of the base not covered with the mask layer.
The method of forming the compound semiconductor layer stack according to [A12], in which an atomic percentage of In atoms in the InGaN layer is 0.5% or more and 30% or less.
A compound semiconductor layer stack including:
a first layer being formed on a base and including an island-shaped Alx1Iny1Ga(1-x1-y1)N;
a second layer being formed on the first layer and including Alx2Iny2Ga(1-x2-y2)N; and
a third layer being formed on an entire surface including a top of the second layer, the third layer including Alx3Ga(1-x3)N,
the third layer having a top surface that is flat,
provided that the following hold true:
0≤x1<1; 0≤x2<1; 0≤x3<1; 0≤y1<1; and 0<y2<1.
The compound semiconductor layer stack according to [B01], in which the first layer has a forward tapered sloped surface and a flat top surface.
The compound semiconductor layer stack according to [B02], in which the second layer is formed at least on the top surface of the first layer.
The compound semiconductor layer stack according to [B03], in which the second layer is formed on the top surface and the sloped surface of the first layer.
The compound semiconductor layer stack according to [B04], in which
T2-t>T2-s
is satisfied, where
T2-t denotes a thickness of a part of the second layer formed on the top surface of the first layer, and
T2-s denotes a thickness of a part of the second layer formed on the sloped surface of the first layer.
The compound semiconductor layer stack according to any one of [B01] to [B05], in which
a mask layer is formed on the base, and
the first layer is formed on a part of the base not covered with the mask layer.
The compound semiconductor layer stack according to [B06], in which the mask layer includes one type of a material selected from the group consisting of SiN, SiO2, and TiO2.
The compound semiconductor layer stack according to any one of [B01] to [B05], in which
the first layer is doped with impurities including Si or Mg, and
a doping concentration is 1×1019 cm−3 or more.
The compound semiconductor layer stack according to any one of [B01] to [B08], in which a multilayer structure of an AlInGaN layer and an AlGaN layer is formed on the third layer.
The compound semiconductor layer stack according to any one of [B01] to [B09], in which the base includes an InGaN layer.
The compound semiconductor layer stack according to [B010], in which an atomic percentage of In atoms in the InGaN layer is 0.5% or more and 30% or less.
A light-emitting device including:
a compound semiconductor layer stack formed on a base;
a first compound semiconductor layer formed on the compound semiconductor layer stack;
an active layer formed on the first compound semiconductor layer;
a second compound semiconductor layer formed on the active layer;
a second electrode electrically coupled to the second compound semiconductor layer; and
a first electrode electrically coupled to the first compound semiconductor layer,
the compound semiconductor layer stack including
a second layer being formed on the first layer and including Alx2Iny2Ga(1-x2-y2)N, and
a third layer being formed on an entire surface including a top of the second layer, the third layer including Alx3Ga(1-x3)N,
the third layer having a top surface that is flat,
provided that the following hold true:
0≤x1<1; 0≤x2<1; 0≤x3<1; 0≤y1<1; and 0<y2<1.
The light-emitting device according to [C01], in which the first layer has a forward tapered sloped surface and a flat top surface.
The light-emitting device according to [C02], in which the second layer is formed at least on the top surface of the first layer.
The light-emitting device according to [C03], in which the second layer is formed on the top surface and the sloped surface of the first layer.
The light-emitting device according to [C04], in which
T2-t>T2-s
is satisfied, where
T2-t denotes a thickness of a part of the second layer formed on the top surface of the first layer, and
T2-s denotes a thickness of a part of the second layer formed on the sloped surface of the first layer.
The light-emitting device according to any one of [C01] to [C05], in which
a mask layer is formed on the base, and
the first layer is formed on a part of the base not covered with the mask layer.
The light-emitting device according to [C06], in which the mask layer includes one type of a material selected from the group consisting of SiN, SiO2, and TiO2.
The light-emitting device according to any one of [C01] to [C05], in which
the first layer is doped with impurities including Si or Mg, and
a doping concentration is 1×1019 cm−3 or more.
The light-emitting device according to any one of [C01] to [C08], in which a multilayer structure of an AlInGaN layer and an AlGaN layer is formed on the third layer.
The light-emitting device according to any one of [C01] to [C09], in which the base includes an InGaN layer.
The light-emitting device according to [C09], in which an atomic percentage of In atoms in the InGaN layer is 0.5% or more and 30% or less.
10 compound semiconductor layer stack
11, 11′ first layer
11A top surface of first layer
11B sloped surface of first layer
12 second layer
13 third layer
13A top surface of third layer
14, 14′ base
14A sapphire substrate or silicon substrate
15 GaN low temperature buffer layer and GaN layer
16 mask layer
17 opening of mask layer
18 multilayer structure (superlattice structure)
18A AlInGaN layer
18B AlGaN layer
20 ridge stripe structure
21 first compound semiconductor layer
22 second compound semiconductor layer
23 active layer (light-emitting layer)
25 first electrode
26 second electrode
27, 28 pad electrode.
Number | Date | Country | Kind |
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2019-079978 | Apr 2019 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2020/014796 | 3/31/2020 | WO | 00 |