The invention relates to a radiation-emitting semiconductor laser comprising—a semiconductor body comprising an active region which is designed to generate electromagnetic radiation, —a resonator which has a first end region and a second end region, and —a first sensor layer which is designed to measure the temperature of the semiconductor body, wherein the active region is located in the resonator in such a way that the electromagnetic radiation generated in the active region during operation is electromagnetic laser radiation, and —the first sensor layer is located in the first active end region of the resonator. The invention also relates to a method for operating a radiation-emitting semiconductor laser.

A semiconductor stack includes a first-conductivity-type layer, a quantum well structure, and a second-conductivity-type layer. The first-conductivity-type layer, the quantum well structure, and the second-conductivity-type layer are stacked in this order. The quantum well structure includes a first semiconductor layer, a second semiconductor layer, and a third semiconductor layer. In the first semiconductor layer and the third semiconductor layer, compositions of the first semiconductor layer and the third semiconductor layer are changed such that a bandgap decreases toward the second semiconductor layer. Transition of an electron is possible between a conduction band of each of the first semiconductor layer and the third semiconductor layer and a valence band of the second semiconductor layer.

A laser structure may include a substrate, an active region arranged on the substrate, and a waveguide arranged on the active region. The waveguide may include a first surface and a second surface that join to form a first angle relative to the active region. A material may be deposited on the first surface and the second surface of the waveguide.

A semiconductor laser element includes a stacked structure body, a second electrode 62, and a first electrode 61; a ridge stripe structure 71 formed of at least part of the stacked structure body is formed; a side structure body 72 formed of the stacked structure body is formed on both sides of the ridge stripe structure 71; the second electrode 62 is separated into a first portion for sending a direct current to the first electrode via a light emitting region and a second portion 62B for applying an electric field to a saturable absorption region; a protection electrode 81 is formed on a portion adjacent to the second portion 62B of the second electrode of at least one side structure body 72; and an insulating layer 56 made of an oxide insulating material is formed to extend from on a portion of the ridge stripe structure 71 to on a portion of the side structure body 72, on which portions neither the second electrode nor the protection electrode 81 is formed.

The light-emitting element of an embodiment outputs a clear optical image while suppressing light output efficiency reduction, and includes a substrate, a light-emitting unit, and a bonding layer. The light-emitting unit has a semiconductor stack, including a phase modulation layer, between first and second electrodes. The phase modulation layer has a base layer and modified refractive index regions, and includes a first region having a size including the second electrode, and a second region. Each gravity center of the second region's modified refractive index region is arranged by an array condition. The light from the stack is a single beam, and regarding a first distance from the substrate to the stack's front surface and a second distance from the substrate to the stack's back surface, a variation amount of the first distance along a direction on the substrate is smaller than a variation amount of the second distance.

A method for manufacturing an optical semiconductor device having a ridge stripe configuration containing an active layer and current blocking layers which embed both sides of the ridge stripe configuration, comprises steps of forming a mask of an insulating film on a surface of a semiconductor layer containing an active layer, forming a ridge stripe configuration by etching a semiconductor layer using gas containing SiCl.sub.4, removing an oxide layer with regard to a Si based residue which is attached on a surface which is etched of the ridge stripe configuration which is formed and removing a Si based residue whose oxide layer is removed.

A quantum cascade semiconductor laser includes a substrate with a main surface including a waveguide area and a distributed Bragg reflection area that are arranged in a direction of a first axis; a laser region provided on the waveguide area, the laser region including a mesa waveguide having first and second side surfaces, and first and second burying regions provided on the first and second side surfaces, respectively; a distributed Bragg reflection region provided on the distributed Bragg reflection area, the distributed Bragg reflection region including a semiconductor wall having first bulk semiconductor regions and first laminate regions that are alternately arrayed in a direction of a second axis intersecting the first axis; and an upper electrode provided on the laser region. Each first bulk semiconductor region includes a bulk semiconductor layer. Each first laminate region includes a stacked semiconductor layer having a plurality of semiconductor layers.

A reproducible method for producing a resonant structure of a distributed-feedback semiconductor laser exhibiting a narrow waveguide of the order of some ten micrometers, the production of the diffraction grating being carried out subsequent to the step of producing the strip is provided. In a last step, a diffraction grating is engraved as a function of a desired precise wavelength.

A light-emitting device is provided. The light-emitting device is configured to emit a radiation and comprises: a substrate; an epitaxial structure on the substrate and comprising a first DBR stack, a light-emitting stack and a second DBR stack and a contact layer in sequence; an electrode; a current blocking layer between the contact layer and the electrode; a first opening formed in the current blocking layer; and a second opening formed in the electrode and within the first opening; wherein a part of the electrode fills in the first opening and contacts the contact layer; and the light-emitting device is devoid of an oxidized layer and an ion implanted layer in the second DBR stack.

A laser diode includes a substrate, an epitaxial structure, an electrode contacting layer and an optical cladding layer. The epitaxial structure is disposed on the substrate, and is formed with a ridge structure opposite to the substrate. The electrode contacting layer is disposed on a top surface of the ridge structure. The optical cladding layer has a refractive index smaller than that of the electrode contacting layer The optical cladding layer includes a first cladding portion which covers side walls of the ridge structure, and a second cladding portion which is disposed on a portion of the top surface of the ridge structure. A method for manufacturing the abovementioned laser diode is also disclosed.