Abstract: Provided is a nitride-based semiconductor light-emitting element having improved carrier injection efficiency into the well layer. The element comprises a substrate (5) formed from a hexagonal-crystal gallium nitride semiconductor; an n-type gallium nitride semiconductor region (7) disposed on a main surface (S1) of the substrate (5); a light-emitting layer (11) having a single quantum well structure disposed on the n-type gallium nitride semiconductor region (7); and a p-type gallium nitride semiconductor region (19) disposed on the light-emitting layer (11). The light-emitting layer (11) is disposed between the n-type gallium nitride semiconductor region (7) and the p-type gallium nitride semiconductor region (19). The light-emitting layer (11) comprises a well layer (15), a barrier layer (13), and a barrier layer (17). The well layer (15) is InGaN.

Abstract: Provided is a group-III nitride semiconductor laser device with a laser cavity of high lasing yield, on a semipolar surface of a support base in which the c-axis of a hexagonal group-III nitride is tilted toward the m-axis. First and second fractured faces 27, 29 to form the laser cavity intersect with an m-n plane. The group-III nitride semiconductor laser device 11 has a laser waveguide extending in a direction of an intersecting line between the m-n plane and the semipolar surface 17a. For this reason, it is feasible to make use of emission by a band transition enabling the low threshold current. In a laser structure 13, a first surface 13a is opposite to a second surface 13b. The first and second fractured faces 27, 29 extend from an edge 13c of the first surface 13a to an edge 13d of the second surface 13b. The fractured faces are not formed by dry etching and are different from conventionally-employed cleaved facets such as c-planes, m-planes, or a-planes.

Abstract: A group III nitride semiconductor device having a gallium nitride based semiconductor film with an excellent surface morphology is provided. A group III nitride optical semiconductor device 11a includes a group III nitride semiconductor supporting base 13, a GaN based semiconductor region 15, an active layer active layer 17, and a GaN semiconductor region 19. The primary surface 13a of the group III nitride semiconductor supporting base 13 is not any polar plane, and forms a finite angle with a reference plane Sc that is orthogonal to a reference axis Cx extending in the direction of a c-axis of the group III nitride semiconductor. The GaN based semiconductor region 15 is grown on the semipolar primary surface 13a. A GaN based semiconductor layer 21 of the GaN based semiconductor region 15 is, for example, an n-type GaN based semiconductor, and the n-type GaN based semiconductor is doped with silicon.

Abstract: Provided is a method of fabricating a nitride semiconductor light emitting device, and this method can reduce degradation of a well layer during formation of a p-type gallium nitride based semiconductor region and a barrier layer. After growth of a gallium nitride based semiconductor region 13, a barrier layer 21a is grown on a substrate 11. The barrier layer 21a is formed at a growth temperature TB during a period from a time t1 to t2. The growth temperature TB (=T2) is in the range of not less than 760 Celsius degrees and not more than 800 Celsius degrees. At the time t2, the growth of the barrier layer 21a is completed. After the growth of the barrier layer 21a, a well layer 23a is grown on the substrate 11 without interruption of growth. The well layer 23a is formed at a growth temperature TW (=T2) during a period from the time t2 to t3. The growth temperature TW is the same as the growth temperature TB and can be in the range of not less than 760 Celsius degrees and not more than 800 Celsius degrees.

Abstract: A high electron mobility transistor includes a free-standing supporting base having a III nitride region, a first III nitride barrier layer which is provided on the first III nitride barrier layer, a III nitride channel layer which is provided on the first III nitride barrier layer and forms a first heterojunction with the first III nitride barrier layer, a gate electrode provided on the III nitride channel layer so as to exert an electric field on the first heterojunction, a source electrode on the III nitride channel layer and the first III nitride barrier, and a drain electrode on the III nitride channel layer and the first III nitride barrier. The III nitride channel layer has compressive internal strain, and the piezoelectric field of the III nitride channel layer is oriented in the direction from the supporting base towards the first III nitride barrier layer.

Abstract: Disclosed is a nitride-based semiconductor light emitting device with excellent light extraction efficiency. A light emitting device 11 includes a support base 13 and a semiconductor laminate 15. The semiconductor laminate 15 includes an n-type GaN-based semiconductor region 17, an active layer 19, and a p-type GaN-based semiconductor region 21. The n-type GaN-based semiconductor region 17, the active layer 19, and the p-type GaN-based semiconductor region 21 are mounted on a principal surface 13a, and are arranged in the direction of a predetermined axis Ax orthogonal to the principal surface 13a. A rear surface 13b of the support base 13 is inclined with respect to a plane orthogonal to a reference axis extending in the c-axis direction of a hexagonal gallium nitride semiconductor of the support base 13. A vector VC represents the c-axis direction. A surface morphology M of the rear surface 13b has a plurality of protrusions 23 protruding in the direction of a <000-1>-axis.

Abstract: A III-nitride semiconductor device has a support base comprised of a III-nitride semiconductor and having a primary surface extending along a first reference plane perpendicular to a reference axis inclined at a predetermined angle ALPHA with respect to the c-axis of the III-nitride semiconductor, and an epitaxial semiconductor region provided on the primary surface of the support base. The epitaxial semiconductor region includes a plurality of GaN-based semiconductor layers. The reference axis is inclined at a first angle ALPHA1 in the range of not less than 10 degrees, and less than 80 degrees from the c-axis of the III-nitride semiconductor toward a first crystal axis, either one of the m-axis and a-axis. The reference axis is inclined at a second angle ALPHA2 in the range of not less than ?0.30 degrees and not more than +0.30 degrees from the c-axis of the III-nitride semiconductor toward a second crystal axis, the other of the m-axis and a-axis.

Abstract: Provided is a gallium nitride based semiconductor light-emitting device with a structure capable of enhancing the degree of polarization. A light-emitting diode 11a is provided with a semiconductor region 13, an InGaN layer 15 and an active layer 17. The semiconductor region 13 has a primary surface 13a having semipolar nature, and is made of GaN or AlGaN. The primary surface 13a of the semiconductor region 13 is inclined at an angle ? with respect to a plane Sc perpendicular to a reference axis Cx which extends in a direction of the [0001] axis in the primary surface 13a. The thickness D13 of the semiconductor region 13 is larger than the thickness DInGaN of the InGaN layer 17, and the thickness DInGaN of the InGaN layer 15 is not less than 150 nm. The InGaN layer 15 is provided directly on the primary surface 13a of the semiconductor region 13 and is in contact with the primary surface 13a.

Abstract: A Group III nitride semiconductor device has a semiconductor region, a metal electrode, and a transition layer. The semiconductor region has a surface comprised of a Group III nitride crystal. The semiconductor region is doped with a p-type dopant. The surface is one of a semipolar surface and a nonpolar surface. The metal electrode is provided on the surface. The transition layer is formed between the Group III nitride crystal of the semiconductor region and the metal electrode. The transition layer is made by interdiffusion of a metal of the metal electrode and a Group III nitride of the semiconductor region.

Abstract: A semiconductor device has a satisfactory ohmic contact on a p-type principal surface tilting from a c-plane. The principal surface 13a of a p-type semiconductor region 13 extends along a plane tilting from a c-axis (axis <0001>) of hexagonal group-III nitride. A metal layer 15 is deposited on the principal surface 13a of the p-type semiconductor region 13. The metal layer 15 and the p-type semiconductor region 13 are separated by an interface 17 such that the metal layer functions as a non-alloy electrode. Since the hexagonal group-III nitride contains gallium as a group-III element, the principal surface 13a comprising the hexagonal group-III nitride is more susceptible to oxidation compared to the c-plane of the hexagonal group-III nitride. The interface 17 avoids an increase in amount of oxide after the formation of the metal layer 15 for the electrode.

Abstract: Provided is a group-III nitride semiconductor laser device with a laser cavity allowing for a low threshold current, on a semipolar surface of a support base in which the c-axis of a hexagonal group-III nitride is tilted toward the m-axis. First and second fractured faces 27, 29 to form the laser cavity intersect with an m-n plane. The group-III nitride semiconductor laser device 11 has a laser waveguide extending in a direction of an intersecting line between the m-n plane and the semipolar surface 17a. For this reason, it is feasible to make use of emission by a band transition enabling the low threshold current. In a laser structure 13, a first surface 13a is opposite to a second surface 13b. The first and second fractured faces 27, 29 extend from an edge 13c of the first surface 13a to an edge 13d of the second surface 13b. The fractured faces are not formed by dry etching and are different from conventionally-employed cleaved facets such as c-planes, m-planes, or a-planes.

Abstract: An active layer 17 is provided so as to emit light having a light emission wavelength in the range of 440 to 550 nm. A first conduction type gallium nitride-based semiconductor region 13, the active layer 17, and a second conduction type gallium nitride-based semiconductor region 15 are disposed in a predetermined axis Ax direction. The active layer 17 includes a well layer composed of hexagonal InXGa1-XN (0.16?X?0.35, X: strained composition), and the indium composition X is represented by a strained composition. The a-plane of the hexagonal InXGa1-XN is aligned in the predetermined axis Ax direction. The thickness of the well layer is in the range of more than 2.5 nm to 10 nm. When the thickness of the well layer is set to 2.5 nm or more, a light emitting device having a light emission wavelength of 440 nm or more can be formed.

Abstract: A III-nitride semiconductor laser device is provided with a laser structure and an electrode. The laser structure includes a support base which comprises a hexagonal III-nitride semiconductor and has a semipolar primary surface, and a semiconductor region provided on the semipolar primary surface. The electrode is provided on the semiconductor region. The semiconductor region includes a first cladding layer of a first conductivity type GaN-based semiconductor, a second cladding layer of a second conductivity type GaN-based semiconductor, and an active layer provided between the first cladding layer and the second cladding layer. The laser structure includes first and second fractured faces intersecting with an m-n plane defined by the m-axis of the hexagonal III-nitride semiconductor and an axis normal to the semipolar primary surface. A laser cavity of the III-nitride semiconductor laser device includes the first and second fractured faces.

Abstract: A group-III nitride light-emitting device is provided. An active layer having a quantum well structure is grown on a basal plane of a gallium nitride based semiconductor region. The quantum well structure is formed in such a way as to have an emission peak wavelength of 410 nm or more. The thickness of a well layer is 4 nm or more, and 10 nm or less. The well layer is composed of InXGa1-XN (0.15?X<1, where X is a strained composition). The basal plane of the gallium nitride based semiconductor region is inclined at an inclination angle within the range of 15 degrees or more, and 85 degrees or less with reference to a {0001} plane or a {000-1} plane of a hexagonal system group III nitride. The basal plane in this range is a semipolar plane.

Abstract: In the method of fabricating a quantum well structure which includes a well layer and a barrier layer, the well layer is grown at a first temperature on a sapphire substrate. The well layer comprises a group III nitride semiconductor which contains indium as a constituent. An intermediate layer is grown on the InGaN well layer while monotonically increasing the sapphire substrate temperature from the first temperature. The group III nitride semiconductor of the intermediate layer has a band gap energy larger than the band gap energy of the InGaN well layer, and a thickness of the intermediate layer is greater than 1 nm and less than 3 nm in thickness. The barrier layer is grown on the intermediate layer at a second temperature higher than the first temperature. The barrier layer comprising a group III nitride semiconductor and the group III nitride semiconductor of the barrier layer has a band gap energy larger than the band gap energy of the well layer.

Abstract: A group III nitride semiconductor optical device 11a has a group III nitride semiconductor substrate 13 having a main surface 13a forming a finite angle with a reference plane Sc orthogonal to a reference axis Cx extending in a c-axis direction of the group III nitride semiconductor and an active layer 17 of a quantum-well structure, disposed on the main surface 13a of the group III nitride semiconductor substrate 13, including a well layer 28 made of a group III nitride semiconductor and a plurality of barrier layers 29 made of a group III nitride semiconductor. The main surface 13a exhibits semipolarity. The active layer 17 has an oxygen content of at least 1×1017 cm?3 but not exceeding 8×1017 cm?3. The plurality of barrier layers 29 contain an n-type impurity other than oxygen by at least 1×1017 cm?3 but not exceeding 1×1019 cm?3 in an upper near-interface area 29u in contact with a lower interface 28Sd of the well layer 28 on the group III nitride semiconductor substrate side.

Abstract: In a GaN based semiconductor optical device 11a, the primary surface 13a of the substrate 13 tilts at a tilting angle toward an m-axis direction of the first GaN based semiconductor with respect to a reference axis “Cx” extending in a direction of a c-axis of the first GaN based semiconductor, and the tilting angle is 63 degrees or more, and is less than 80 degrees. The GaN based semiconductor epitaxial region 15 is provided on the primary surface 13a. On the GaN based semiconductor epitaxial region 15, an active layer 17 is provided. The active layer 17 includes one semiconductor epitaxial layer 19. The semiconductor epitaxial layer 19 is composed of InGaN. The thickness direction of the semiconductor epitaxial layer 19 tilts with respect to the reference axis “Cx.” The reference axis “Cx” extends in the direction of the [0001] axis. This structure provides the GaN based semiconductor optical device that can reduces decrease in light emission characteristics due to the indium segregation.

Abstract: A group III nitride semiconductor laser is provided that has a good optical confinement property and includes an InGaN well layer having good crystal quality. An active layer 19 is provided between a first optical guiding layer 21 and a second optical guiding layer 23. The active layer 19 can include well layers 27a, 27b, and 27c and further includes at least one first barrier layer 29a provided between the well layers. The first and second optical guiding layers 21 and 23 respectively include first and second InGaN regions 21a and 23a smaller than the band gap E29 of the first barrier layer 29a, and hence the average refractive index nGUIDE of the first and second optical guiding layers 21 and 23 can be made larger than the refractive index n29 of the first barrier layer 29a. Thus, good optical confinement is achieved. The band gap E29 of the first barrier layer 29a is larger than the band gaps E21 and E23 of the first and second InGaN regions 21a and 23a.

Abstract: A III-nitride semiconductor optical device has a support base comprised of a III-nitride semiconductor, an n-type gallium nitride based semiconductor layer, a p-type gallium nitride based semiconductor layer, and an active layer. The support base has a primary surface at an angle with respect to a reference plane perpendicular to a reference axis extending in a c-axis direction of the III-nitride semiconductor. The n-type gallium nitride based semiconductor layer is provided over the primary surface of the support base. The p-type gallium nitride based semiconductor layer is doped with magnesium and is provided over the primary surface of the support base. The active layer is provided between the n-type gallium nitride based semiconductor layer and the p-type gallium nitride based semiconductor layer over the primary surface of the support base. The angle is in the range of not less than 40° and not more than 140°. The primary surface demonstrates either one of semipolar nature and nonpolar nature.

Abstract: A method of fabricating a nitride semiconductor laser comprises preparing a substrate having a plurality of marker structures and a crystalline mass made of a hexagonal gallium nitride semiconductor. The primary and back surfaces of the substrate intersect with a predetermined axis extending in the direction of a c-axis of the hexagonal gallium nitride semiconductor. Each marker structure extends along a reference plane defined by the c-axis and an m-axis of the hexagonal gallium nitride semiconductor. The method comprises cutting the substrate along a cutting plane to form a wafer of hexagonal gallium nitride semiconductor, and the cutting plane intersects with the plurality of the marker structures. The wafer has a plurality of first markers, each of which extends from the primary surface to the back surface of the wafer, and each of the first markers comprises part of each of the marker structures. The primary surface of the wafer is semipolar or nonpolar.