A semiconductor laser diode is specified, the semiconductor laser diode includes a semiconductor layer sequence having an active layer having a main extension plane and which, in operation, is configured to generate light in an active region and emit light via a light-outcoupling surface, the active region extending from a back surface opposite the light-outcoupling surface to the light-outcoupling surface along a longitudinal direction in the main extension plane, the semiconductor layer sequence having a surface region on which a first cladding layer is applied in direct contact, the first cladding layer having a transparent material from a material system different from the semiconductor layer sequence, and the first cladding layer being structured and having a first structure.

A laminate (22) is formed on a semiconductor substrate (10). Two or more grooves (54) are formed in the laminate (22). A mesa (24) with two grooves among the two or more grooves (54) positioned on both sides is formed. An insulating resin film (30) is embedded into the two or more grooves (54). A first opening (32) is formed at the insulating resin film (30) embedded in one of the two or more grooves (54) and an electrode (46) extracted upward from a bottom surface (36) is formed. A first side surface (34) of the insulating resin film (30) is inclined in a forward tapered direction.

There is provided a semiconductor element containing gallium nitride. The semiconductor element includes a semiconductor layer including a first surface having a first region and a second region that is a projecting portion having a strip shape and projecting relative to the first region or a recessed portion having a strip shape and being recessed relative to the first region. Of the first surface, at least one of surfaces of the first region and the second region includes a crystal plane having a plane orientation different from a (000-1) plane orientation and a (1-100) plane orientation.

The semiconductor laser element includes: a substrate; a first semiconductor layer disposed above a main surface of the substrate; an active layer that is disposed above the first semiconductor layer and generates light; and a second semiconductor layer) disposed above the active layer. In a top view of a front-side end portion of the semiconductor laser element from which the light is emitted, an end surface of the second semiconductor layer includes an inclined portion with respect to an end surface of the first semiconductor layer.

A light emitting device according to an embodiment of the present disclosure includes: a semi-insulating substrate; a semiconductor layer; a semiconductor stacked body; a buried layer; and a non-continuous lattice plane. The semi-insulating substrate has a first surface and a second surface that are opposed to each other. The semiconductor layer is stacked on the first surface of the semi-insulating substrate. The semiconductor layer has electrical conductivity. The semiconductor stacked body is stacked above the first surface of the semi-insulating substrate with the semiconductor layer interposed in between. The semiconductor stacked body has a light emitting region and includes a ridge section on the semi-insulating substrate side. The light emitting region is configured to emit laser light. The buried layer is provided around the ridge section of the semiconductor stacked body. The non-continuous lattice plane is provided between the semi-insulating substrate and the semiconductor stacked body.

A light-emitting device includes a light diffusing member that diffuses light emitted from a light source so that an object to be measured is irradiated with the light; and a holding unit that is provided on plural wires connected to the light source and holds the light diffusing member.

A multilayer interconnect is described which enables electrically connecting a complex distribution of VCSEL or other light emitter elements in a large high density addressable array. The arrays can include many groups of VCSEL elements interspersed among each other to form a structured array. Each group can be connected to a contact pad so that each group of light emitter elements can be activated separately.

The invention relates to a semiconductor laser apparatus having a layer stack which comprises a first resonator mirror, a second resonator mirror and an active zone which is arranged between the first and second resonator mirrors and which is suitable for emitting electromagnetic radiation. A charge carrier barrier is arranged around a central region of the active zone.

A light-emitting device includes a light emission section (Em), a separation groove (152), and a high reflectance region (Hr). The light emission section (Em) includes a stack structure (100) including an active layer (100), a first reflector (110), and a second reflector (120). The active layer (130) performs light emission by current injection. The first reflector (110) and the second reflector (120) are stacked in a first direction with the active layer (130) interposed therebetween. The separation groove (152) is provided symmetrically around the light emission section (Em) on an emission surface of light from the stack structure (100) in the first direction. The separation groove (152) is dug in the stack structure (100) in the first direction. The high resistance region (Hr) is provided in the stack structure (100) on the outer side of an outermost shape of the separation groove (152) on the emission surface. The high resistance region (Hr) has electrical resistance higher than that of the light emission section (Em).

There are provided a surface emission laser 10, a surface emission laser array in which the surface emission laser 10 is arrayed two-dimensionally, and a surface emission laser manufacturing method that enable efficient injection of a current to an active layer 200b, while suppressing deterioration of the crystallinity of layers stacked above a contact area.

The present technology provides a surface emission laser 10 including a substrate 100, and a mesa structure 200 formed on the substrate 100, in which the mesa structure 200 includes at least a part of a first multilayer film reflector 200a stacked on the substrate 100, an active layer 200b stacked on the first multilayer film reflector 200a, and a second multilayer film reflector 200c stacked on the active layer 200b, and an impurity area 800 is provided over a contact area CA that is adjacent to the mesa structure 200, and contacts an electrode 600, and a side wall section of a portion of the mesa structure 200 which portion includes the first multilayer film reflector 200a.