摘要:
A gallium nitride based semiconductor device is provided which includes a gallium nitride based semiconductor film with a flat c-plane surface provided on a gallium oxide wafer. A light emitting diode LED includes a gallium oxide support base 32 having a primary surface 32a of monoclinic gallium oxide, and a laminate structure 33 of Group III nitride. A semiconductor mesa of the laminate structure 33 includes a low-temperature GaN buffer layer 35, an n-type GaN layer 37, an active layer 39 of a quantum well structure, and a p-type gallium nitride based semiconductor layer 37. The p-type gallium nitride based semiconductor layer 37 includes, for example, a p-type AlGaN electron block layer and a p-type GaN contact layer. The primary surface 32a of the gallium oxide support base 32 is inclined at an angle of not less than 2 degrees and not more than 4 degrees relative to a (100) plane of monoclinic gallium oxide. Owing to this inclination, the gallium nitride based semiconductor epitaxially grown on the primary surface 32a of the gallium oxide support base has a flat surface.
摘要翻译:提供了一种氮化镓基半导体器件,其包括在氧化镓晶片上设置有平坦c面的氮化镓基半导体膜。 发光二极管LED包括具有单斜氧化镓的主表面32a的氧化镓载体基底32和III族氮化物的叠层结构33。 层压结构33的半导体台面包括低温GaN缓冲层35,n型GaN层37,量子阱结构的有源层39和p型氮化镓基半导体层37. p 型氮化镓系半导体层37例如包括p型AlGaN电子阻挡层和p型GaN接触层。 氧化镓载体基体32的主表面32a相对于单斜晶系氧化镓的(100)面倾斜2度以上4度以下。 由于该倾斜,在氧化镓载体基体的主表面32a上外延生长的氮化镓基半导体具有平坦的表面。
摘要:
A method for forming an epitaxial wafer is provided as one enabling growth of a gallium nitride based semiconductor with good crystal quality on a gallium oxide region. In step S107, an AlN buffer layer 13 is grown. In step S108, at a time t5, a source gas G1 containing hydrogen, trimethylaluminum, and ammonia, in addition to nitrogen, is supplied into a growth reactor 10 to grow the AlN buffer layer 13 on a primary surface 11a. The AlN buffer layer 13 is so called a low-temperature buffer layer. After a start of film formation of the buffer layer 13, in step S109 supply of hydrogen (H2) is started at a time t6. At the time t6, H2, N2, TMA, and NH3 are supplied into the growth reactor 10. A supply amount of hydrogen is increased between times t6 and t7, and at the time t7 the increase of hydrogen is terminated to supply a constant amount of hydrogen. At the time t7, H2, TMA, and NH3 are supplied into the growth reactor 10.
摘要:
Provided is a method for fabricating a wafer product including an active layer grown on a gallium oxide substrate and allowing an improvement in emission intensity. In step S105, a buffer layer 13 comprised of a Group III nitride such as GaN, AlGaN, or AlN is grown at 600 Celsius degrees on a primary surface 11a of a gallium oxide substrate 11. After the growth of the buffer layer 13, while supplying a gas G2, which contains hydrogen and nitrogen, into a growth reactor 10, the gallium oxide substrate 11 and the buffer layer 13 are exposed to an atmosphere in the growth reactor 11 at 1050 Celsius degrees. A Group III nitride semiconductor layer 15 is grown on the modified buffer layer. The modified buffer layer includes, for example, voids. The Group III nitride semiconductor layer 15 can be comprised of GaN and AlGaN. When the Group III nitride semiconductor layer 15 is formed of these materials, excellent crystal quality is obtained on the modified buffer layer 14.
摘要:
Provided is a method for fabricating a wafer product including an active layer grown on a gallium oxide substrate and allowing an improvement in emission intensity. In step S105, a buffer layer 13 comprised of a Group III nitride such as GaN, AlGaN, or AlN is grown at 600 Celsius degrees on a primary surface 11a of a gallium oxide substrate 11. After the growth of the buffer layer 13, while supplying a gas G2, which contains hydrogen and nitrogen, into a growth reactor 10, the gallium oxide substrate 11 and the buffer layer 13 are exposed to an atmosphere in the growth reactor 11 at 1050 Celsius degrees. A Group III nitride semiconductor layer 15 is grown on the modified buffer layer. The modified buffer layer includes, for example, voids. The Group III nitride semiconductor layer 15 can be comprised of GaN and AlGaN. When the Group III nitride semiconductor layer 15 is formed of these materials, excellent crystal quality is obtained on the modified buffer layer 14.
摘要:
A method for forming an epitaxial wafer is provided as one enabling growth of a gallium nitride based semiconductor with good crystal quality on a gallium oxide region. In step S107, an AlN buffer layer 13 is grown. In step S108, at a time t5, a source gas G1 containing hydrogen, trimethylaluminum, and ammonia, in addition to nitrogen, is supplied into a growth reactor 10 to grow the AlN buffer layer 13 on a primary surface 11a. The AlN buffer layer 13 is so called a low-temperature buffer layer. After a start of film formation of the buffer layer 13, in step S109 supply of hydrogen (H2) is started at a time t6. At the time t6, H2, N2, TMA, and NH3 are supplied into the growth reactor 10. A supply amount of hydrogen is increased between times t6 and t7, and at the time t7 the increase of hydrogen is terminated to supply a constant amount of hydrogen. At the time t7, H2, TMA, and NH3 are supplied into the growth reactor 10.
摘要:
A gallium nitride based semiconductor device is provided which includes a gallium nitride based semiconductor film with a flat c-plane surface provided on a gallium oxide wafer. A light emitting diode LED includes a gallium oxide support base 32 having a primary surface 32a of monoclinic gallium oxide, and a laminate structure 33 of Group III nitride. A semiconductor mesa of the laminate structure 33 includes a low-temperature GaN buffer layer 35, an n-type GaN layer 37, an active layer 39 of a quantum well structure, and a p-type gallium nitride based semiconductor layer 37. The p-type gallium nitride based semiconductor layer 37 includes, for example, a p-type AlGaN electron block layer and a p-type GaN contact layer. The primary surface 32a of the gallium oxide support base 32 is inclined at an angle of not less than 2 degrees and not more than 4 degrees relative to a (100) plane of monoclinic gallium oxide. Owing to this inclination, the gallium nitride based semiconductor epitaxially grown on the primary surface 32a of the gallium oxide support base has a flat surface.
摘要翻译:提供了一种氮化镓基半导体器件,其包括在氧化镓晶片上设置有平坦c面的氮化镓基半导体膜。 发光二极管LED包括具有单斜氧化镓的主表面32a的氧化镓载体基底32和III族氮化物的叠层结构33。 层压结构33的半导体台面包括低温GaN缓冲层35,n型GaN层37,量子阱结构的有源层39和p型氮化镓基半导体层37. p 型氮化镓系半导体层37例如包括p型AlGaN电子阻挡层和p型GaN接触层。 氧化镓载体基体32的主表面32a相对于单斜晶系氧化镓的(100)面倾斜2度以上4度以下。 由于该倾斜,在氧化镓载体基体的主表面32a上外延生长的氮化镓基半导体具有平坦的表面。
摘要:
There are provided a Si(1-v-w-x)CwAlxNv substrate that achieves high crystallinity and low costs, an epitaxial wafer, and manufacturing methods thereof.A method for manufacturing a Si(1-v-w-x)CwAlxNv substrate according to the present invention includes the steps of preparing a different type of substrate 11 and growing a Si(1-v-w-x)CwAlxNv layer having a main surface on the different type of substrate 11. The component ratio x+v at the main surface of the Si(1-v-w-x)CwAlxNv layer is 0
摘要翻译:提供了实现高结晶度和低成本的Si(1-v-w-x)C w Al x N v衬底,外延晶片及其制造方法。 根据本发明的用于制造Si(1-vwx)CwAlxNv衬底的方法包括以下步骤:制备不同类型的衬底11并在不同类型的衬底上生长具有主表面的Si(1-vwx)C w Al x N v层 Si(1-vwx)CwAlxNv层的主表面的分量比x + v为0
摘要:
Affords methods of growing III nitride single crystals of favorable crystallinity with excellent reproducibility, and the III nitride crystals obtained by the growth methods. One method grows a III nitride single crystal (3) inside a crystal-growth vessel (11), the method being characterized in that a porous body formed from a metal carbide, whose porosity is between 0.1% and 70% is employed in at least a portion of the crystal-growth vessel (11). Employing the crystal-growth vessel (11) makes it possible to discharge from 1% to 50% of a source gas (4) inside the crystal-growth vessel (11) via the pores in the porous body to the outside of the crystal-growth vessel (11).
摘要:
Affords a GaN single-crystal mass, a method of its manufacture, and a semiconductor device and method of its manufacture, whereby when the GaN single-crystal mass is being grown, and when the grown GaN single-crystal mass is being processed into a substrate or like form, as well as when an at least single-lamina semiconductor layer is being formed onto a single-crystal GaN mass in substrate form to manufacture semiconductor devices, cracking is controlled to a minimum. The GaN single-crystal mass 10 has a wurtzitic crystalline structure and, at 30° C., its elastic constant C11 is from 348 GPa to 365 GPa and its elastic constant C13 is from 90 GPa to 98 GPa; alternatively its elastic constant C11 is from 352 GPa to 362 GPa.
摘要:
An AlxGayIn1-x-yN substrate in which particles having a grain size of at least 0.2 μm on a surface of the AlxGayIn1-x-yN substrate are at most 20 in number when a diameter of the AlxGayIn1-x-yN substrate is two inches, and a cleaning method with which the AlxGayIn1-x-yN substrate can be obtained are provided. Further, an AlxGayIn1-x-yN substrate in which, in a photoelectron spectrum of a surface of the AlxGayIn1-x-yN substrate by X-ray photoelectron spectroscopy with a detection angle of 10°, a ratio between a peak area of C1s electrons and a peak area of N1s electrons (C1s electron peak area/N1s electron peak area) is at most 3, and a cleaning method with which the AlxGayIn1-x-yN substrate can be obtained are provided. Still further, an AlN substrate in which, in a photoelectron spectrum of a surface of the AlN substrate by X-ray photoelectron spectroscopy with a detection angle of 10°, a ratio between a peak area of Al2s electrons and a peak area of N1s electrons (Al2s electron peak area/N1s electron peak area) is at most 0.65 and a cleaning method with which the AlN substrate can be obtained are provided.
摘要翻译:在其中Al的表面上具有至少0.2μm的晶粒尺寸的颗粒的Al x N y N y N y 在1-xy N衬底中,当Al x N 2的直径为至多20个数量时, 在1-xy N衬底中的Ga 2 y是两英寸,并且其中Al x Ga y Y y >可以获得在1-xy N衬底中。 此外,在Al-N-N基底中,在Al 2 O 3的表面的光电子光谱中, 通过X射线光电子能谱检测角度为10°,在1-xy N衬底中,峰面积C < SUB> 1s电子和N 1s电子的峰面积(C 1s电子峰面积/ N 1s电子峰面积) 至多为3,并且可以获得可以获得Al x N y Na y In 1-xy N衬底的清洁方法。 此外,AlN基板,其中,通过X射线光电子能谱法测定AlN基板的表面的光电子光谱,检测角度为10°,Al 2基板的峰面积 电子和N 1s电子的峰面积(Al 2 S 3电子峰面积/ N 1s电子峰面积)为0.65以下,清洗 提供了可以获得AlN衬底的方法。