Monolithic pixel detectors, systems and methods for the detection and imaging of electromagnetic radiation with high spectral and spatial resolution comprise a Si wafer with a CMOS processed pixel readout bonded to an absorber wafer in wafer bonds comprising conducting bonds between doped, highly conducting charge collectors in the readout and highly conducting regions in the absorber wafer and poorly conducting bonds between regions of high resistivity.

A photodiode, such as a linear mode avalanche photodiode can be made free of excess noise via having a superlattice multiplication region that allows only one electrical current carrier type, such as an electron or a hole, to accumulate enough kinetic energy to impact ionize when biased, where the layers are lattice matched. A photodiode can be constructed with i) a lattice matched pair of a first semiconductor alloy and a second semiconductor alloy in a superlattice multiplication region, ii) an absorber region, and iii) a semiconductor substrate. A detector with multiple photodiodes can be made with these construction layers in order to have a cutoff wavelength varied anywhere from 1.7 to 4.9 μm as well as a noise resulting from a dark current at a level such that an electromagnetic radiation signal with the desired minimum wavelength cutoff can be accurately sensed by the photodiode.

Devices, systems, and methods are provided for reducing electrical and optical crosstalk in photodiodes. A photodiode may include a first layer with passive material, the passive material having no electric field. The photodiode may include a second layer with an absorbing material, the second layer above the first layer. The photodiode may include a diffused region with a buried p-n junction. The photodiode may include an active region with the buried p-n junction and having an electric field greater than zero. The photodiode may include a plateau structure based on etching through the second layer to the first layer, the etching performed at a distance of fifteen microns or less from the buried p-n junction.

A photodetection device includes a pixel matrix in which each pixel includes a barrier photodetector. The pixel matrix includes an absorption layer, a barrier layer, a contact layer, and at least one separation element to delimit the pixels. At least one separation element extends above the contact layer, and forms at least one depletion zone that extends locally in the contact layer, to block the lateral circulation of charge carriers.

An imaging unit includes a photoelectric conversion layer including a compound semiconductor and having a light incident surface, and a light shielding portion provided in an optical path of light incident on the light incident surface and shielding light having a wavelength of less than 450 nm.

A multi-level semiconductor device, the device including: a first level including integrated circuits; a second level including a structure designed to conduct electromagnetic waves, where the second level is disposed above the first level, where the first level includes crystalline silicon; an oxide layer disposed between the first level and the second level; and a plurality of electromagnetic modulators, where the second level is bonded to the oxide layer, and where the bonded includes oxide to oxide bonds.

A photodiode for use in detecting X-rays and/or gamma rays is disclosed. The photodiode comprises InGaP arranged and configured to absorb X-rays and/or gamma-rays incident on the photodiode and generate charge-carriers in response thereto. The detector may be provided in an X-ray or gamma-ray photon counting spectrometer.

A 3D micro display, the 3D micro display including: a first single crystal layer including a first plurality of light emitting diodes (LEDs); a second single crystal layer including a second plurality of light emitting diodes (LEDs), where the first single crystal layer includes at least ten individual first LED pixels, where the second single crystal layer includes at least ten individual second LED pixels, where the first plurality of light emitting diodes (LEDs) emits a first light with a first wavelength, where the second plurality of light emitting diodes (LEDs) emits a second light with a second wavelength, where the first wavelength and the second wavelength differ by greater than 10 nm; and further including a third single crystal layer including at least one LED driving circuit.

Disclosed herein is an image sensor comprising: a plurality of avalanche photodiodes (APDs); wherein each of the APDs comprises a radiation absorption layer that comprises an absorption region and an amplification region; wherein the absorption region is configured to generate charge carriers therein from a particle of radiation absorbed by the radiation absorption layer; wherein the absorption region comprises an InGaAs layer sandwiched between InP layers; wherein the amplification region has an electric field therein, the electric field having a field strength sufficient to cause an avalanche of the charge carriers in the amplification region.

A solid-state imaging element including a photoelectric conversion layer of a first electrical conductivity type including a plurality of pixel regions, an electrode electrically coupled to the photoelectric conversion layer and provided for each of the pixel regions, a semiconductor layer provided between the electrode and the photoelectric conversion layer and having a bandgap larger than a bandgap of the photoelectric conversion layer, a diffusion part disposed in a vicinity of an edge of the pixel region and including an impurity of a second electrical conductivity type that is diffused from the semiconductor layer across the photoelectric conversion layer, and a non-diffusion part provided inside the diffusion part and not including the impurity of the second electrical conductivity type in the photoelectric conversion layer.