The end-face incident type semiconductor light receiving device has a first light absorbing region on the main surface side of the semiconductor substrate and causes light incident from the end-face of the semiconductor substrate to enter the first light absorbing region by reflection or refraction, and the first reflective section is provided on the main surface side of the semiconductor substrate to cause light transmitted through the light absorbing region to enter the first light absorbing region, and a single second reflective section is provided on the back surface for causing the light reflected by the first reflective section and transmitted through the first light absorbing region to reflect directly toward the first light absorbing region.

A light detection device including a substrate, a first light detector, a second light detector, and a switch element is provided. The first light detector is disposed on the substrate and includes a first active layer. The second light detector is disposed between the substrate and the first light detector and includes a second active layer. The switch element is disposed on the substrate. A horizontal projection of the second active layer on the substrate completely falls within a horizontal projection of the first active layer on the substrate. A negative electrode of the first light detector and a negative electrode of the second light detector are electrically connected to the switch element via a first metal layer.

An image sensor capable of recording both spectral and polarization properties of light using a single chip device includes an at least 2048 by 2048 array of superpixels. Each superpixel includes an array of spectral pixels, and an adjacent array of polarization pixels. Each spectral pixel includes a spectral filter and a stack of photodiodes, where each photodiode has a different quantum efficiency and is, therefore, sensitive to a different wavelength of light passed by the spectral filter. Each polarization pixel includes a polarization filter and a stack of photodiodes, similar to the spectral pixel photodiode stacks.

Metasurface elements, integrated systems incorporating such metasurface elements with light sources and/or detectors, and methods of the manufacture and operation of such optical arrangements and integrated systems are provided. Systems and methods for integrating transmissive metasurfaces with other semiconductor devices or additional metasurface elements, and more particularly to the integration of such metasurfaces with substrates, illumination sources and sensors are also provided. The metasurface elements provided may be used to shape output light from an illumination source or collect light reflected from a scene to form two unique patterns using the polarization of light. In such embodiments, shaped-emission and collection may be combined into a single co-designed probing and sensing optical system.

A curved FPA comprises an array of detectors, with mesas etched between the detectors such that they are electrically and physically isolated from each other. Metallization deposited at the bottom of the mesas reconnects the detectors electrically and thereby provides a common ground between them. Strain induced by bending the FPA into a curved shape is across the metallization and any backfill epoxy, rather than across the detectors. Indium bumps are evaporated onto respective detectors for connection to a readout integrated circuit (ROIC). An ROIC coupled to the detectors is preferably thinned, and the backside of the ROIC may also include mesas such that the ROIC is reticulated.

A photodetector including: an amplification region that includes a PN junction provided in a depth direction in a semiconductor layer and that is to be electrically coupled to a cathode; a separation region that defines a pixel region including the amplification region; a hole accumulation region that is provided along a side surface of the separation region and that is to be electrically coupled to an anode; and a gate electrode provided in a region between the amplification region and the hole accumulation region and stacked over the semiconductor layer with a gate insulating film interposed therebetween.

Provided is a photoelectric detector, comprising: a silicon layer (110), the silicon layer (110) comprising a first-doping-type doped region (111); a germanium layer (120) in contact with the silicon layer (110), the germanium layer (120) comprising a second-doping-type doped region (121); and a silicon nitride waveguide (130), the silicon nitride waveguide (130) being arranged surrounding the germanium layer (120) along the extension directions of at least three side walls of the germanium layer (120), wherein the silicon nitride waveguide (130) is used for transmitting an optical signal and coupling the optical signal to the germanium layer (120), and the germanium layer (120) is used for detecting the optical signal and converting the optical signal into an electrical signal.

According to the present disclosure, techniques related to manufacturing and applications of power photodiode structures and devices based on group-III metal nitride and gallium-based substrates are provided. More specifically, embodiments of the disclosure include techniques for fabricating photodiode devices comprising one or more of GaN, AlN, InN, InGaN, AlGaN, and AlInGaN, structures and devices. Such structures or devices can be used for a variety of applications including optoelectronic devices, photodiodes, power-over-fiber receivers, and others.

A high efficiency configuration for a string of solar cells comprises series-connected solar cells arranged in an overlapping shingle pattern. Front and back surface metallization patterns may provide further increases in efficiency.

Disclosed is an opto-electronic device including a semiconducting substrate, a layered interface including at least one layer, the layered interface having a first surface in contact with a surface of the semiconducting substrate and the layered interface being adapted for passivating the surface of the semiconducting substrate, the layered interface having a second surface and the layered interface being adapted for electrically insulating the first surface from the second surface, and a textured surface structure including a plurality of nanowires and a transparent dielectric coating, the textured surface structure being in contact with the second surface of the layered interface, the plurality of nanowires protruding from the second surface and the plurality of nanowires being embedded between the second surface and the transparent dielectric coating.