A light-emitting element includes a mesa structure in which a first compound semiconductor layer of a first conductivity type, an active layer, and a second compound semiconductor layer of a second conductivity type are disposed in that order, wherein at least one of the first compound semiconductor layer and the second compound semiconductor layer has a current constriction region surrounded by an insulation region extending inward from a sidewall portion of the mesa structure; a wall structure disposed so as to surround the mesa structure; at least one bridge structure connecting the mesa structure and the wall structure, the wall structure and the bridge structure each having the same layer structure as the portion of the mesa structure in which the insulation region is provided; a first electrode; and a second electrode disposed on a top face of the wall structure.

Structures for integrated lasers, systems including integrated lasers, and associated fabrication methods. A ring waveguide and a seed region are arranged interior of the ring waveguide. A laser strip extends across a portion of the ring waveguide. The laser strip has an end contacting the seed region and another opposing end. The laser strip includes a laser medium and a p-n junction capable of generating electromagnetic radiation. The p-n junction of the laser strip is aligned with a portion of the ring waveguide.

A semiconductor laser including current block layers disposed between a p-type clad layer and a p-type light guide layer and a current confinement region which is a region between the current block layers is configured as follows. A width of an opening portion of an insulating layer is made narrow above a wide portion of the current confinement region in which the wide portion, a tapered portion, a narrow portion, a tapered portion and the wide portion are disposed in this order between an incidence side (HR side) and an emission side (AR side), and both ends of the wide portion are covered by an insulating layer. According to such a configuration, it is possible to suppress generation of super luminescence in the wide portion, and it is thus possible to achieve improvement in beam quality and higher output of the beam.

A semiconductor optical device 1 includes an active layer 4 provided on a substrate 2, a clad layer 5 provided on the active layer 4, and a contact layer 7 provided on the clad layer 5. The contact layer 7 contains a first impurity and a second impurity different from the first impurity. A semiconductor light source includes the active layer 4 provided on the substrate 2, the clad layer 5 provided on the active layer 4, and the contact layer 7 provided on the clad layer 5. The contact layer 7 contains the first impurity and the second impurity different from the first impurity.

A light-emitting element includes a mesa structure in which a first compound semiconductor layer of a first conductivity type, an active layer, and a second compound semiconductor layer of a second conductivity type are disposed in that order, wherein at least one of the first compound semiconductor layer and the second compound semiconductor layer has a current constriction region surrounded by an insulation region extending inward from a sidewall portion of the mesa structure; a wall structure disposed so as to surround the mesa structure; at least one bridge structure connecting the mesa structure and the wall structure, the wall structure and the bridge structure each having the same layer structure as the portion of the mesa structure in which the insulation region is provided; a first electrode; and a second electrode disposed on a top face of the wall structure.

A semiconductor apparatus with improved heat removal and improved heat flow to a heat sink is provided. The semiconductor apparatus includes a p-type semiconductor. An n-p tunnel junction is positioned within an epitaxial structure of the p-type semiconductor. A metal contact layer is connected to the n-p tunnel junction through an alloyed n-type contact interface. The n-p tunnel junction improves heat flow from the semiconductor through an alloyed contact interface formed between the tunnel junction and the metal contact layer which has lower thermal and electrical resistance in comparison to a conventional metallurgically abrupt interface of a p-type contact.

A semiconductor visible laser with broadband emission and reduced speckling is provided. Conventional lasers with narrow spectral emission cause undesired speckles. The invention reduces laser speckles by producing a broadband laser emission. The laser comprises a multitude of quantum dot layers having quantum dots that have inhomogeneity in size, density, or composition. Methods of constructing such a laser are also provided.

An optoelectronic component includes an active zone that generates electromagnetic radiation, wherein the electromagnetic radiation is guided in a guide plane, the electromagnetic radiation is output essentially in the guide plane, the active zone emits stray radiation laterally with respect to the guide plane, an electrical contact pad is provided, the contact pad is arranged outside the guide plane, the contact pad is formed by a surface at least partially covered by a conductive layer, the surface has inclined partial faces, and the electrically conductive layer on at least a subset of the inclined faces of the contact pad is configured to be so thin that electromagnetic stray radiation is emitted via the subset of the inclined faces.

A laser diode includes a ridge portion, channel portions located adjacent to the ridge portion such that the ridge portion is sandwiched, the channel portions being shorter in height than the ridge portion, terrace portions adjacent to opposite sides of the respective channel portions from the ridge portion and longer in height than the channel portions, supporting portions provided over the respective channel portions, separated from side surfaces of the ridge portion or side surfaces of terrace portions or both, and made of resin, a ceiling portion including first portions provided over the supporting portions and second portions continuous with the first portions and located over the respective channel portions with hollow portions interposed therebetween, the ceiling portion being made of resin, and a metal layer provided over the ceiling portion and connected to an upper surface of the ridge portion.

Methods for fabricating ultraviolet laser diode devices include providing substrate members comprising gallium and nitrogen or aluminum and nitrogen, forming an epitaxial material overlying a surface region of the substrate members, patterning the epitaxial material to form epitaxial mesa regions, depositing a bond media on at least one of the epitaxial mesa regions, bonding the bond media on at least one of the epitaxial mesa regions to a handle substrate, subjecting the sacrificial layer to an energy source to initiate release of the substrate member and transfer the at least one of the epitaxial mesa regions to the handle substrate, and processing the at least one of the epitaxial mesa regions to form the ultraviolet laser diode device.