A device and process in which a single continuous depositional layer of a polycrystalline photoactive material is deposited on an integrated charge storage, amplification, and readout circuit with an irregular surface wherein the polycrystalline photoactive material is comprised of a II-VI semiconductor compound or alloys of II-VI compounds.

Disclosed herein is radiation detector comprising: a radiation absorption layer configured to generate electric signals by absorbing radiation particles; an electronics layer comprising an electronic system configured to process or interpret the signals; a flexible PCB configured to receive output from the electronic system; wherein the radiation absorption layer and the flexible PCB are mounted on a same side of the electronics layer.

Methods and devices for detecting incident radiation are provided. The methods and devices use high quality single-crystals of photoactive semiconductor compounds in combination with metal anodes and metal cathodes that provide for enhanced photodetector performance.

In a described example, an apparatus includes: a photon detector array with a first signal output pad coupled to a photon detector array pixel; a die carrier comprising a readout integrated circuit (ROIC) die and a conductor layer having conductors that couple a first signal input pad on the conductor layer to an input signal lead of the ROIC die; and the first signal output pad coupled to the first signal input pad.

An X-ray device including a sensing panel is provided. The sensing panel includes a first pixel and a second pixel. The second pixel is disposed adjacent to the first pixel in a top view direction. The first pixel includes a first photoelectric conversion layer. The second pixel includes a second photoelectric conversion layer. The first photoelectric conversion layer and the second photoelectric conversion layer belong to different layers.

Provided is a stable CdZnTe monocrystalline substrate having a small leakage current even when a high voltage is applied and having a lower variation in resistivity with respect to variations in applied voltage values. A semiconductor wafer comprising a cadmium zinc telluride monocrystal having a zinc concentration of 4.0 at % or more and 6.5 at % or less and a chlorine concentration of 0.1 ppm by mass or more and 5.0 ppm by mass or less, wherein the semiconductor wafer has a resistivity of 1.0×10.sup.7 Ωcm or more and 1.0×10.sup.8 Ωcm or less when a voltage of 900 V is applied, and wherein a ratio (variation ratio) of the resistivity at application of 0 V to the resistivity at application of a voltage of 900 V is 20% or less.

An X-ray system includes an X-ray generation unit configured to generate X-rays; an X-ray detection unit including at least one X-ray sensor that includes an indirect bandgap, perovskite semiconductor material, the X-ray sensor being configured to record the X-rays; and a control unit that controls a generation of the X-rays and a detection of the X-rays at the X-ray detection unit.

In a described example, an apparatus includes: a photon detector array with a first signal output pad coupled to a photon detector array pixel; a die carrier comprising a readout integrated circuit (ROIC) die and a conductor layer having conductors that couple a first signal input pad on the conductor layer to an input signal lead of the ROIC die; and the first signal output pad coupled to the first signal input pad.

The present disclosure provides a flat panel detector and a medical image detection device. The flat panel detector includes a base substrate, wherein the base substrate is divided into a plurality of detection units, each detection unit includes a first absorbing layer and a second absorbing layer, both of which are arranged on the base substrate in a laminating manner, the second absorbing layer is located on one side, away from the base substrate, of the first absorbing layer, and an energy level of rays absorbed by the second absorbing layer is smaller than that of rays absorbed by the first absorbing layer; a voltage supply electrode structure; and an output circuit, electrically connected to the voltage supply electrode structure and configured to output a first detection signal of the first absorbing layer and a second detection signal of the second absorbing layer.

A device includes a network having a first material (e.g. electron donor, hole transporting material, p-type semiconductor) for transporting positive electrical charges and a second material (e.g. electron acceptor, electronic transporting material, n-type semiconductor) for transporting negative electrical charges. The first and second materials are dispersed within the network to form a plurality of electrical junctions. A plurality of nanoparticles are dispersed within the network, wherein the nanoparticles have at least one dimension larger than twice an exciton Bohr radius for the nanoparticles and at least one dimension less than 100 nm. In use, the nanoparticles convert incoming radiation into free positive and negative electrical charges for transportation by the first and second materials respectively.