A quantum cascade laser of an embodiment includes a semiconductor stacked body in which a ridge waveguide is provided. The semiconductor stacked body includes an active layer including a quantum well region including a layer including Al; and the active layer emits laser light. The layer that includes Al includes first regions, and a second region interposed between the first regions; the first region includes Al oxide and reaches a prescribed depth inward from an outer edge of the active layer along a direction parallel to a surface of the active layer in a cross section orthogonal to the optical axis; and the second region does not include Al oxide.

A quantum cascade laser has a core region including a first injection layer, an active region, and a second injection layer. The active region includes a first well layer, a second well layer, a third well layer, a first barrier layer, and a second barrier layer. The first barrier layer is disposed between the first well layer and the second well layer and separates the first well layer from the second well layer. The second barrier layer is disposed between the second well layer and the third well layer and separates the second well layer from the third well layer. The first barrier layer has a thickness of 1.2 nm or less, and the second barrier layer has a thickness of 1.2 nm or less.

A low voltage laser device having an active region configured for one or more selected wavelengths of light emissions.

UV laser devices, systems, and methods are shown and/or described herein. Included are a method, device or system for VECSEL and MECSEL lasers including both barrier-pumped and in-well pumped lasers. Also disclosed is a method of manufacturing gain chips for use in the lasers, arrangements of lasers, and selection of proper non-linear crystal (NLC) for use in the device.

A gain medium for semiconductor optical amplifier in high-power operation includes a substrate with n-type doping; a lower clad layer formed overlying the substrate; a lower optical confinement stack overlying the lower clad layer; an active layer comprising a multi-quantum-well heterostructure with multiple well layers characterized by about 0.8% to 1.2% compressive strain respectively separated by multiple barrier layers characterized by about −0.1% to −0.5% tensile strain. The active layer overlays the lower optical confinement stack. The gain medium further includes an upper optical confinement stack overlying the active layer, the upper optical confinement stack being set thinner than the lower optical confinement stack; an upper clad layer overlying the upper optical confinement stack; and a p-type contact layer overlying the upper clad layer.

An ICL comprises: a plurality of IC stages, wherein each of the IC stages comprises: a hole injector; an electron injector; an active region coupled to the hole injector and the electron injector and comprising a first layer, wherein the first layer comprises a first material, and wherein the first material comprises InAsP or AlInAsP; a conduction band running through the hole injector, the electron injector, and the active region; and a valence band running through the hole injector, the electron injector, and the active region.

In some implementations, a method may include forming a quantum well (QW) layer using an epitaxial growth process, where the epitaxial growth process is performed according to a first growth mode to form the QW layer. The method may include forming a quantum well barrier (QWB) layer using the epitaxial growth process, where the epitaxial growth process is performed according to a second growth mode to form the QWB layer. In some implementations, a nitrogen flux used in the first growth mode is different from a nitrogen flux used in the second growth mode. In some implementations, a gallium flux used in the first growth mode is different from a gallium flux used in the second growth mode.

Disclosed herein are multi-layered optically active regions for semiconductor light-emitting devices (LEDs) that incorporate intermediate carrier blocking layers, the intermediate carrier blocking layers having design parameters for compositions and doping levels selected to provide efficient control over the carrier injection distribution across the active regions to achieve desired device injection characteristics. Examples of embodiments discussed herein include, among others: a multiple-quantum-well variable-color LED operating in visible optical range with full coverage of RGB gamut, a multiple-quantum-well variable-color LED operating in visible optical range with an extended color gamut beyond standard RGB gamut, a multiple-quantum-well light-white emitting LED with variable color temperature, and a multiple-quantum-well LED with uniformly populated active layers.

A semiconductor layer structure may include a substrate, a blocking layer disposed over the substrate, and one or more epitaxial layers disposed over the blocking layer. The blocking layer may have a thickness of between 50 nanometers (nm) and 4000 nm. The blocking layer may be configured to suppress defects from the substrate propagating to the one or more epitaxial layers. The one or more epitaxial layers may include a quantum-well layer that includes a quantum-well intermixing region formed using a high temperature treatment.

Surface-emitting laser devices and light-emitting devices including the same are provided. A surface-emitting laser device can include: a first reflective layer and a second reflective layer; and an active region disposed between the first reflective layer and the second reflective layer, wherein the first reflective layer includes a first group first reflective layer and a second group first reflective layer, and the second reflective layer includes a first group second reflective layer and a second group second reflective layer.