A method of manufacturing a semiconductor element includes: a first providing step comprising providing a structure body comprising a semiconductor stacked body, the structure body including first surfaces that include surfaces defining at least one first recess; a first forming step comprising forming a first rough-surface portion at or inward of at least a portion of the surfaces defining the first recess of the structure body; a second forming step comprising forming a first metal layer at a first surface side of the structure body; a second providing step comprising providing a substrate on which a second metal layer is disposed; and a bonding step comprising heating the first metal layer and the second metal layer in a state in which the first metal layer and the second metal layer face each other.

A light-emitting device can include a conductive support structure comprising a metal; a GaN-based semiconductor structure disposed on the conductive support structure, the GaN-based semiconductor structure including a p-type GaN-based layer, a GaN-based active layer and an n-type GaN-based layer, in which the GaN-based semiconductor structure has a first surface, a side surface and a second surface, in which the first surface, relative to the second surface, is proximate to the conductive support structure, in which the second surface is opposite to the first surface, in which the conductive support structure is thicker than the p-type GaN-based semiconductor layer, and the conductive support structure is thicker than the n-type GaN-based semiconductor layer; a p-type electrode disposed on the conductive support structure; an n-type electrode disposed on the second surface of the GaN-based semiconductor structure; and a passivation layer disposed on the side surface and the second surface of the GaN-based semiconductor structure.

A group III-nitride semiconductor device comprises a light emitting semiconductor structure comprising a p-type layer and an n-type layer operable as a light emitting diode or laser. On top of the p-type layer there is arranged an n+ or n++-type layer of a group III-nitride, which is transparent to the light emitted from the underlying semiconductor structure and of sufficiently high electrical conductivity to provide lateral spreading of injection current for the light-emitting semiconductor structure.

Provided are a group III nitride composite substrate having a low sheet resistance and produced with a high yield, and a method for manufacturing the same, as well as a method for manufacturing a group III nitride semiconductor device using the group III nitride composite substrate. A group III nitride composite substrate includes a group III nitride film and a support substrate formed from a material different in chemical composition from the group III nitride film. The group III nitride film is joined to the support substrate in one of a direct manner and an indirect manner. The group III nitride film has a thickness of 10 m or more. A sheet resistance of a group III-nitride-film-side main surface is 200 /sq or less.

A manufacturing method of an optoelectronic semiconductor device includes: providing a matrix substrate, which comprises a substrate and a matrix circuit disposed on the substrate; transferring a plurality of micro-sized optoelectronic semiconductor elements from a temporary substrate to the matrix substrate, wherein the micro-sized optoelectronic semiconductor elements are separately disposed on the matrix substrate, and at least one electrode of each micro-sized optoelectronic semiconductor element is electrically connected with the matrix circuit; forming a protective layer completely covering the micro-sized optoelectronic semiconductor elements, wherein the height of the protective layer is greater than the height of the micro-sized optoelectronic semiconductor elements; and grinding the protective layer until a residual on a back surface of each micro-sized optoelectronic semiconductor element and the back surface are removed to expose a new surface.

Wavelength converters, including polarization-enhanced carrier capture converters, for solid state lighting devices, and associated systems and methods are disclosed. A solid state radiative semiconductor structure in accordance with a particular embodiment includes a first region having a first value of a material characteristic and being positioned to receive radiation at a first wavelength. The structure can further include a second region positioned adjacent to the first region to emit radiation at a second wavelength different than the first wavelength. The second region has a second value of the material characteristic that is different than the first value, with the first and second values of the characteristic forming a potential gradient to drive electrons, holes, or both electrons and holes in the radiative structure from the first region to the second region. In a further particular embodiment, the material characteristic includes material polarization.

A semiconductor chip of a light emitting diode includes a substrate, and an N-type gallium nitride layer, a quantum well layer, and a P-type gallium nitride layer stacked on the substrate successively, an N-type electrode electrically connected to the N-type gallium nitride layer, and a P-type electrode electrically connected to the P-type gallium nitride layer. The quantum well layer includes at least one quantum barrier and at least one quantum well stacked successively in sequence, wherein the growth pressure of the quantum barrier and the growth pressure of the quantum well are different, such that the interface crystal quality between the quantum well and the quantum barrier of the quantum well layer can be greatly improved to enhance the luminous efficiency of the semiconductor chip.

A semiconductor light emitting device including a substrate, an electrode and a light emitting region is provided. The substrate may have protruding portions formed in a repeating pattern on substantially an entire surface of the substrate while the rest of the surface may be substantially flat. The cross sections of the protruding portions taken along planes orthogonal to the surface of the substrate may be semi-circular in shape. The cross sections of the protruding portions may in alternative be convex in shape. A buffer layer and a GaN layer may be formed on the substrate.

In a general aspect, a method for producing an optoelectronic device includes forming a mechanically-compliant layer on a substrate, and forming a second layer, the mechanically-compliant layer being disposed between the second layer and the substrate. The method also includes performing a relaxation operation to facilitate a release of strain energy in the second layer by the mechanically-compliant layer. The mechanically-compliant layer, the second layer and the relaxation operation are configured such that a surface of the second layer has an extended defect density below a predetermined value. The method also includes forming a light-emitting region, the second layer being disposed between the light-emitting region and the substrate. The extended defect density being below the predetermined value results in a leakage resistance in an active region of the light-emitting region that is higher than 10 milliohms per centimeter-squared (mOhm/cm2).

Provided is a semiconductor light-emitting device for which detrimental effects such as discoloration of an electrode or emission failure due to migration are suppressed even when a joint material containing Ag is used, and a method of producing the same. The semiconductor light-emitting device includes a p-type semiconductor layer, a p-type electrode provided on the p-type semiconductor layer, and a pad provided on the p-type electrode. The p-type electrode at least has an ohmic metal layer placed on the p-type semiconductor layer side and a barrier layer that is placed closer to the pad than the ohmic metal layer and includes a TiN layer. In a top view, when a region of the barrier layer that does not overlap an electrical connection region between the pad and the barrier layer is defined as a surface diffusion inhibiting surface, the surface diffusion inhibiting surface is formed in a circular pattern.