A method includes epitaxially growing a first III-V compound layer over a semiconductive substrate. A second III-V compound layer is epitaxially grown over the first III-V compound layer. A source/drain contact is formed over the second III-V compound layer. A gate structure is formed over the second III-V compound layer. A pattern is formed shielding the gate structure and the source/drain contact, in which a portion of the second III-V compound layer is free from coverage by the pattern.

A light-receiving device includes at least one pixel. The at least one pixel includes a first electrode; a second electrode; and a photoelectric conversion layer between the first electrode and the second electrode. The photoelectric conversion layer is configured to convert incident infrared light into electric charge. The photoelectric conversion layer has a first section and a second section. The first section is closer to the first electrode than the second section, and the second section is closer to the second electrode than the first section. At least one of the first section and the second section have a plurality of surfaces.

Disclosed herein is a method of producing an infrared detector. In certain embodiments, the method includes: forming a planar multi-layer structure including an absorber including a superlattice structure; patterning the planar multi-layer structure; etching the planar multi-layer structure to define a plurality of pixels, the sidewalls of the plurality of pixels includes a sidewall roughness and multiple types of surface oxides; and performing a surface treatment process to the plurality of pixels in order to reduce the sidewall roughness and replace the surface oxides with a chlorinated surface morphology. The surface treatment process may reduce surface current of the infrared detector which may decrease the dark current in the infrared detector.

A method for regulating a photoelectric spectral response range, including: pre-pressurizing a gasket material, and drilling a circular hole at the center of indentation as a sample chamber; padding the sample chamber with a layer of photoelectric material, where two ends of the photoelectric material each are connected to one platinum sheet as an electrode; respectively connecting the two electrodes to probes of a digital source-meter, and using the digital source-meter to apply a 5 V bias voltage to the photoelectric material; placing a pressure calibration substance for pressure calibration; applying a high pressure to the photoelectric material, to make a pressure in the sample chamber reach a preset pressure; irradiating a near-infrared laser onto the photoelectric material through diamonds, controlling the presence or absence of illumination, and using the digital source-meter to display a current-time curve at the preset pressure; and determining a photoelectric spectral response range.

A sensor includes a first image pixel array including first image pixels and a second image pixel array including second image pixels. A polarization layer is disposed between the first image pixels and the second image pixels. Scene light incident upon the second image pixels propagates through the first image pixels and the polarization layer to reach the second image pixels.

An image sensor device includes a semiconductor substrate, a radiation sensing member, a device layer, and a color filter layer. The semiconductor substrate has a photosensitive region and an isolation region surrounding the photosensitive region. The radiation sensing member is embedded in the photosensitive region of the semiconductor substrate. The radiation sensing member has a material different from a material of the semiconductor substrate, and an interface between the radiation sensing member and the isolation region of the semiconductor substrate includes a direct band gap material. The device layer is under the semiconductor substrate and the radiation sensing member. The color filter layer is over the radiation sensing member and the semiconductor substrate.

An infrared-absorbing composition includes particles of an infrared-absorbing coloring agent and a solvent, in which the particles in the infrared-absorbing composition have two or more maximal absorption wavelengths exhibited in a wavelength range of 650 to 1500 nm, and in the range, in a case where an absorbance at a maximal absorption wavelength existing on a second shortest wavelength side is set to 1, an absorbance at a maximal absorption wavelength existing on a shortest wavelength side is 0.6 to 2.0.

An integrated circuit comprises a substrate composed of crystalline semiconductor. An optoelectronic device is formed at the substrate and includes a plurality of transducers. A thin-film semiconductor layer is situated over the optical device, and circuitry is formed at the thin-film semiconductor layer. The circuitry may include a plurality of transistors electrically coupled to the optoelectronic device by a set of layer interconnects.

Various embodiments of the present disclosure are directed towards a method for forming an image sensor in which a device layer has high crystalline quality. According to some embodiments, a hard mask layer is deposited covering a substrate. A first etch is performed into the hard mask layer and the substrate to form a cavity. A second etch is performed to remove crystalline damage from the first etch and to laterally recess the substrate in the cavity so the hard mask layer overhangs the cavity. A sacrificial layer is formed lining cavity, a blanket ion implantation is performed into the substrate through the sacrificial layer, and the sacrificial layer is removed. An interlayer is epitaxially grown lining the cavity and having a top surface underlying the hard mask layer, and a device layer is epitaxially grown filling the cavity over the interlayer. A photodetector is formed in the device layer.

A photodetector including a substrate having a semiconductor material layer, such as a silicon-containing layer, and a germanium-based well embedded in the semiconductor material layer, where a gap is located between a lateral side surface of the germanium-based well and the surrounding semiconductor material layer. The gap between the lateral side surface of the germanium-based well and the surrounding semiconductor material layer may reduce the surface contact area between the germanium-containing material of the well and the surrounding semiconductor material, which may be a silicon-based material. The formation of the gap located between a lateral side surface of the germanium-based well and the surrounding semiconductor material layer may help minimize the formation of crystal defects, such as slips, in the germanium-based well, and thereby reduce the dark current and improve photodetector performance.