A pixel includes, on a first face, first trenches extending parallel to a first direction and regularly spaced in a second direction (orthogonal to the first direction) and second trenches extending parallel to the second direction and regularly spaced in the first direction. The first trenches include first notches, each first notch extending from a first trench and being aligned with a corresponding second trench. The second trenches include second notches, each second notch extending from a second trench and being aligned with a corresponding first trench.

A camera having an integrated dewar cooler assembly (IDCA) with an optical window, and a reduced dark current photodetector disposed within the IDCA to receive light passing through the optical window. The photodetector comprising a semiconductor photo absorbing layer, a semiconductor barrier layer having a thickness and a first side adjacent a side of the photo absorbing layer, the barrier layer exhibiting a valence band energy level substantially equal to the valence band energy level of the photo absorbing layer and a conduction band energy level exhibiting an energy gap in relation to the conduction band of the photo absorbing layer, and a contact area comprising a doped semiconductor, the contact area is adjacent a second side of the barrier layer opposing the first side. The energy gap and/or the thickness of the of the barrier layer is sufficient to minimize charge carriers tunneling and thermalization.

A sensor according to an embodiment of the present disclosure includes a substrate, a diaphragm including a light absorbing film disposed with a cavity interposed between the light absorbing film and the substrate, a beam portion that supports the diaphragm on the substrate, and a temperature sensing element that detects a temperature change of the light absorbing film. The light absorbing film contains a fibrous material or a sheet-like material that absorbs terahertz waves or infrared rays. The mean value of angles formed by a direction of the fibrous material or a planar direction of a sheet and a direction parallel to the substrate is 45 or less at least in a part of a region of the light absorbing film.

The present invention provides an invisible light flat plate detector and a manufacturing method thereof, an imaging apparatus, relates to the field of detection technology, can solve problems that the structure of the invisible light flat plate detector in the prior art is complex and the manufacturing method thereof is tedious. The invisible light flat plate detector of the present invention comprises a plurality of detection units and an invisible light conversion layer provided above the detection units for converting invisible light into visible light, each of the detection units comprising a thin film transistor provided on a substrate, and a first insulation layer, a first electrode, a semiconductor photoelectronic conversion module, a second electrode which are successively provided above the thin film transistor and of which projections on the substrate at least partially overlap with a projection of the thin film transistor on the substrate.

A device is disclosed including a substrate and a floating blinded infrared detector and/or a shunted blinded infrared detector. The floating blinded infrared detector may include an infrared detector coupled to and thermally isolated from the substrate; and a blocking structure disposed above the infrared detector to block external thermal radiation from being received by the infrared detector; and wherein the blocking structure comprises a plurality of openings. The shunted blinded infrared detector may include an additional infrared detector coupled to the substrate; an additional blocking structure disposed above the infrared detector to block external thermal radiation from being received by the additional infrared detector; and a material that thermally couples the additional infrared detector to the substrate and the additional blocking structure. Methods for using and forming the device are also disclosed.

A two-terminal detector has a back-to-back p/n/p SWIR/MWIR stack structure, which includes P-SWIR absorber, N-SWIR, wide bandgap bather, N-MWIR absorber, and P-MWIR layers, with contacts on the P-MWIR and P-SWIR layers. The junction between the SWIR layers and the junction between the MWIR layers are preferably passivated. The detector stack is preferably arranged such that a negative bias applied to the top of the stack reverse-biases the MWIR junction and forward-biases the SWIR junction, such that the detector collects photocurrent from MWIR radiation. A positive bias forward-biases the MWIR junction and reverse-biases the SWIR junction, such that photocurrent from SWIR radiation is collected. A larger positive bias induces electron avalanche at the SWIR junction, thereby providing detector sensitivity sufficient to provide low light level passive amplified imaging. Detector sensitivity in this mode is preferably sufficient to provide high resolution 3-D eye-safe LADAR imaging.

Imaging devices and ranging devices are disclosed. In one example, an imaging device includes a semiconductor substrate, a first pixel array, a second pixel array, and a control unit. In the first pixel array, a first light receiving pixel on the semiconductor substrate has a stacked structure of a first electrode, a photoelectric conversion layer, and a second electrode (80). It photoelectrically converts light in a first wavelength region including the visible light region. In the second pixel array, a second light receiving pixel is provided at a position overlapping the first light receiving pixel in a thickness direction of the semiconductor substrate. It photoelectrically converts light in a second wavelength region including the infrared light region. The control unit drives and controls the second pixel array based on a signal photoelectrically converted by the first pixel array.

An infrared image sensor component includes at least one III-V compound layer on the semiconductor substrate, in which the portion of the III-V compound layer(s) uncovered by the patterns is utilized as active pixel region for detecting the incident infrared ray. The infrared image sensor component includes at least one transistor coupled to the active pixel region, and charge generated by the active pixel region is transmitted to the transistor.

An apparatus for detecting electromagnetic radiation within a target frequency range is provided. The apparatus includes a substrate and one or more resonator structures disposed on the substrate. The substrate can be a dielectric or semiconductor material. Each of the one or more resonator structures has at least one dimension that is less than the wavelength of target electromagnetic radiation within the target frequency range, and each of the resonator structures includes at least two conductive structures separated by a spacing. Charge carriers are induced in the substrate near the spacing when the resonator structures are exposed to the target electromagnetic radiation. A measure of the change in conductivity of the substrate due to the induced charge carriers provides an indication of the presence of the target electromagnetic radiation.

Systems and methods are directed to vertical legs for an infrared detector. For example, an infrared imaging device may include a microbolometer array in which each microbolometer includes a bridge and a vertical leg structure that couples the bridge to a substrate such as a readout integrated circuit. The vertical leg structure may run along a path that is parallel to a plane defined by the bridge and may be oriented perpendicularly to the plane. The path may be disposed within, below, or above the plane defined by the bridge.