A photodetection element that includes: a substrate with a high infrared transmittance in a desired wavelength region; an electron barrier layer of a type-I superlattice structure, the electron barrier layer being formed above the substrate and lattice-matched to the substrate; and a light-receiving layer of a type-II superlattice structure, formed in contact with the electron barrier layer.

A method of manufacturing a lead salt thin film on a substrate by seeding a substrate with a lead salt solution (e.g., PbSe, PbS, or PbTe) to form a seeded substrate comprising lead salt seed crystals, and growing the lead salt thin film upon the substrate by exposing the seeded substrate to a chemical bath comprising the lead salt solution at a predetermined growth temperature. A lead salt thin film manufactured by the process. A photonic crystal microchip comprising the lead salt thin film. A gas sensing device comprising a diode laser, a mid-infrared photodetector, and the photonic crystal microchip. A method of detecting a hydrocarbon gas, comprising exposing a gas sample to the gas sensing device, and determining the content of hydrocarbon gases in the gas sample.

Mercury cadmium telluride (MCT) dual band photodiode elements are described that include an n-type barrier region interposed between first and second p-type regions. The first p-type region is arranged to absorb different IR wavelengths to the second p-type region in order that the photodiode element can sense two IR bands. A portion of the second p-type region is type converted using ion-beam milling to produce a n-type region that interfaces with the second p-type region and the n-type barrier region.

An IR photodetector includes an electrically conductive layer, a first dielectric layer over the electrically conductive layer, and a phase change material layer over the first dielectric layer. The IR photodetector further includes first and second electrically conductive contacts coupled to the phase change material layer, and a graphene layer over the phase change material layer and having a perforated pattern therein. The IR photodetector includes circuitry configured to apply a bias voltage between the first and second electrically conductive contacts, and detect a sensing current in the phase change material layer caused by IR radiation received by the graphene layer, the IR radiation having a frequency range based upon the bias voltage.

A semiconductor structure configured to implement an optically controlled field effect transistor (FET). In one embodiment, a normally-off, optically controlled FET is realized as a semiconductor structure comprising various regions configured to implement a voltage controlled, normally on, high voltage FET region having integrated thereon a photoconductive region configured to reduce a gate-to-source voltage of the FET in response to light incident upon the photoconductive region so as to turn the FET on.

A device is provided that comprises a first layer deposited onto a second layer. The second layer comprises a lightly doped n-type or p-type semiconductor drift layer, and the first layer comprises a high-k material with a dielectric constant that is at least two times higher than the value of the second layer. A metal Schottky contact is formed on the first layer and a metal ohmic contact is formed on the second layer. Under reverse bias, the dielectric constant discontinuity leads to a very low electric field in the second layer, while the electron barrier created by the first layer stays almost flat. Under forward bias, electrons flow through the first layer, into the metal ohmic contact. For small values of conduction band offset or valence band offset between the first layer and the second layer, the device is expected to support efficient electron or hole transport.

A light detection device includes a photo detector and a circuit board connected to the photo detector by conductive connection parts. In this light detection device, the photo detector includes a substrate, a semiconductor layer provided on one surface of the substrate, a first groove dividing the semiconductor layer into sections for respective pixels, and first electrodes provided on the semiconductor layer and serving as the pixels. Each of the conductive connection part contains indium. Each of the first electrode includes a Ti layer and a Pt layer stacked in this order on the semiconductor layer, and the conductive connection parts are provided on the Pt layers of the first electrodes.

A light detection device includes a photo detector and a circuit board connected to the photo detector by conductive connection parts. In this light detection device, the photo detector includes a substrate, a semiconductor layer provided on one surface of the substrate, a first groove dividing the semiconductor layer into sections for respective pixels, and first electrodes provided on the semiconductor layer and serving as the pixels. Each of the conductive connection part contains indium. Each of the first electrode includes a Ti layer and a Pt layer stacked in this order on the semiconductor layer, and the conductive connection parts are provided on the Pt layers of the first electrodes.

A sensing element of an infrared detector including a first absorber configured to form a first set of minority carriers upon receipt of an infrared flux, a collector, a first barrier disposed between the first absorber and the collector, a second absorber configured to form a second set of minority carriers upon receipt of the infrared flux, and a second barrier disposed between the second absorber and the collector. In response to a voltage being applied to the collector, the first and second set of minority carriers are collected at the collector.

A sensing element of an infrared detector including a first absorber configured to form a first set of minority carriers upon receipt of an infrared flux, a collector, a first barrier disposed between the first absorber and the collector, a second absorber configured to form a second set of minority carriers upon receipt of the infrared flux, and a second barrier disposed between the second absorber and the collector. In response to a voltage being applied to the collector, the first and second set of minority carriers are collected at the collector.