A light emitting device, includes a selective growth mask layer 44; a first light reflection layer 41 thinner than the selective growth mask layer 44; a laminated structure including a first compound semiconductor layer 21, an active layer 23, and a second compound semiconductor layer 22, the first compound semiconductor layer 21 being formed on the first light reflection layer 41; and a second electrode 32 formed on the second compound semiconductor layer 22, and a second light reflection layer 42, in which the second light reflection layer 42 is opposed to the first light reflection layer 41, and the second light reflection layer is not formed on an upper side of the selective growth mask layer 44.

A light-emitting device that includes a substrate, and at least one column portion, wherein the column portion includes a first semiconductor layer of a first conductivity type, a second semiconductor layer of a second conductivity type different from the first conductivity type, and a light-emitting layer provided between the first semiconductor layer and the second semiconductor layer, the first semiconductor layer is provided between the substrate and the light-emitting layer, the light-emitting layer includes a first well layer, and a barrier layer, the barrier layer includes a first layer provided between the first semiconductor layer and the first well layer, and the first layer has a cubic crystal structure.

Disclosed is a current-injection organic semiconductor laser diode comprising a pair of electrodes, an optical resonator structure, and one or more organic layers including a light amplification layer composed of an organic semiconductor, which has a sufficient overlap between the distribution of exciton density and the electric field intensity distribution of the resonant optical mode during current injection to emit laser light.

A nitride semiconductor light-emitting device with periodic gain active layers includes an n-type semiconductor layer, a p-type semiconductor layer and a resonator. The device further includes a plurality of active layers disposed between the n-type and p-type semiconductor layers so as to correspond to a peak intensity position of light existing in the resonator and at least one interlayer disposed between the active layers. The active layer disposed at the p-type semiconductor layer side has a larger light emission intensity than the active layer disposed at the n-type semiconductor layer side.

A laser device includes: a substrate formed from material transparent at a laser wavelength; a first reflecting layer to reflect at least some incident radiation at the laser wavelength; a layer including a gain medium for providing stimulated emission of radiation at the laser wavelength, and positioned between the first reflecting layer and the substrate; a second reflecting layer on an opposite side of the substrate from the first reflecting layer to reflect at least some incident radiation at the laser wavelength; a spatial light modulator in an optical cavity comprising the first and second reflecting layers, and comprising an array of elements each corresponding to a different path for radiation in the optical cavity; and a computer controller that, during operation, causes the spatial light modulator to selectively vary an intensity or phase of radiation in the optical cavity to provide variable transverse spatial mode output of the radiation.

[Object] To provide a semiconductor laser element capable of preventing current leakage in junction-down mounting and a method of producing the semiconductor laser element.

[Solving Means] A semiconductor laser element according to the present technology includes: a stacked body. The stacked body includes a substrate, an n-type semiconductor layer that is formed on the substrate, is formed of an n-type semiconductor material, and has a core that is a defect concentration region, an active layer that is formed on the n-type semiconductor layer, and a p-type semiconductor layer that is formed on the active layer and is formed of a p-type semiconductor material, and has a recessed portion formed from a surface of the p-type semiconductor layer to have a depth reaching the core and an ion implantation region that is formed by implanting ions into a region including the core.

A nitride semiconductor laser element includes a nitride semiconductor stack body and a protective film. The nitride semiconductor stack body includes first and second nitride semiconductor layers and an active layer disposed between the first nitride semiconductor layer and the second nitride semiconductor layer. The nitride semiconductor stack body defines a light-emission-side end face intersecting a face of the active layer on a second nitride semiconductor layer side, and a light-reflection-side end face intersecting the face of the active layer on the second nitride semiconductor layer side. The protective film is disposed on the light-emission-side end face of the nitride semiconductor stack body. The protective film includes, in the order from the light-emission-side end face, a first film that is a crystalline film containing oxygen and aluminum and/or gallium, a second film that is a nitride crystalline film, and a third film containing aluminum and oxygen.

This semiconductor laser device includes a semiconductor laser chip and a spatial light modulator SLM optically coupled to the semiconductor laser chip. The semiconductor laser chip LDC includes an active layer 4, a pair of cladding layers 2 and 7 sandwiching the active layer 4, a diffraction grating layer 6 optically coupled to the active layer 4, and a drive electrode E3 that is disposed between the cladding layer 2 and the spatial light modulator SLM and supplies an electric current to the active layer 4, and the drive electrode E3 is positioned within an XY plane and has a plurality of openings as viewed from a Z-axis direction and has a non-periodic structure.

Provided is a surface emitting laser device including a plurality of surface emitting laser elements and capable of significantly reducing the crosstalk of light and the formation of a dark line. The surface emitting laser device includes: a mounting substrate; a surface emitting laser array including a plurality of surface emitting laser elements arranged side by side on the mounting substrate; a plurality of light absorption layers formed on the plurality of surface emitting laser elements, respectively, and each including an opening; and a plurality of wavelength conversion plates formed on the plurality of light absorption layers, respectively, and each including a fluorescent plate and a light reflection film covering a side surface of the fluorescent plate.

Photonic devices having Al.sub.1-xSc.sub.xN and Al.sub.yGa.sub.1-yN materials, where Al is Aluminum, Sc is Scandium, Ga is Gallium, and N is Nitrogen and where 0<x≤0.45 and 0≤y≤1.