A short-wave infra-red, SWIR, radiation detection device comprises: a first metallic layer providing a first set of connections from a readout circuit to respective cells of a matrix, the metallic layer reflecting SWIR wavelength radiation. Each matrix cell comprises at least one stack of layers including: a first layer of doped semiconductor material formed on the first metallic layer; an at least partially microcrystalline semiconductor layer formed over the first doped layer; a second layer of semiconductor material formed on the microcrystalline semiconductor layer; at least one microcrystalline semiconductor layer; and in some embodiments a second metallic layer interfacing the microcrystalline semiconductor layer(s), the interface being responsive to incident SWIR radiation to generate carriers within the stack. The stack has a thickness T=λ/2N between reflective surfaces of the first and second metallic layers.

A hybrid optical and/or electronic system includes a first planar structure having a first functionality and made of at least one first material, and a second planar structure having a second functionality and made of at least one second material different from the first material, the first and second planar structures being assembled by an assembly layer, at least one of the planar structures being disposed on a rigid substrate, the system comprising at least one active zone used for implementing the functionalities, and at least one neutral zone not used to implement the functionalities and disposed at the periphery of the active zone, the system also comprising recesses made in at least one neutral zone of the planar structure which is not disposed on the rigid substrate and is referred to as hollowed-out planar structure.

Image sensor, mobile terminal, image capturing method are provided. Pixel array of image sensor includes preset quantity of pixel units, pixel unit includes first and second pixels that are dual pixel focusing pixels, first pixel includes red, green, and blue subpixels, second pixel includes green subpixel and infrared subpixel, and at least one of red and blue subpixels, and each subpixel is arranged in four-in-one manner; position of infrared subpixel in second pixel is same as position of red subpixel, green subpixel, blue subpixel, first combination of subpixels, or second combination of subpixels in first pixel; or position of half the infrared subpixel in second pixel is same as position of half the red subpixel, half the green subpixel, or half the blue subpixel in first pixel, and half an infrared subpixel in each of two adjacent second pixels is combined to form entire infrared subpixel.

A semiconductor device that level-shifts a negative voltage and/or a positive voltage is provided. The semiconductor device includes a first transistor, a second transistor, a third transistor, a fourth transistor, a first capacitor, an input terminal, and an output terminal. A first terminal of the first transistor is electrically connected to a first terminal of the second transistor and the output terminal. A second terminal of the second transistor is electrically connected to a first terminal of the third transistor. A first terminal of the fourth transistor is electrically connected to a gate of the second transistor and a first terminal of the first capacitor, and a second terminal of the first capacitor is electrically connected to the input terminal. The first transistor, the second transistor, the third transistor, and the fourth transistor are of the same polarity.

A light-receiving device of an embodiment of the present disclosure includes a photoelectric conversion layer that includes a first compound semiconductor with a first conductivity type and absorbs a wavelength of an infrared region, a first semiconductor layer formed on the photoelectric conversion layer, and an insulation layer formed to surround the photoelectric conversion layer and the first semiconductor layer, the first semiconductor layer having a second conductivity-type region at a middle region excluding a periphery facing the photoelectric conversion layer.

A dual band photodetector includes a first band absorber layer is configured to absorb incident light in a first wavelength spectral band and a second band absorber layer configured to absorb incident light in a second wavelength spectral band. The dual band photodetector further includes an electron-photon blocking (EPB) layer located between the respective layers and includes at least one high band gap layer and at least one intervening layer. The difference in refractive index between the at least one high band gap layer and the at least one intervening layer form a distributed brag reflector (DBR) designed to reflect wavelengths corresponding with radiative recombination photons emitted from at least the first absorber layer to reduce optical crosstalk between the first band absorber layer and the second band absorber layer.

Multicolor, stacked detector devices, focal plane arrays including multicolor, stacked detector devices, and methods of fabricating the same are disclosed. In one embodiment, a stacked multicolor detector device includes a first detector and a second detector. The first detector includes a first detector structure and a first ground plane adjacent the first detector structure. The second detector includes a second detector structure and a second ground plane adjacent the second detector structure. At least one of the first ground plane and the second ground plane is transmissive to radiation in a predetermined spectral band. The first detector and the second detector are in a stacked relationship.

Short-wave infrared (SWIR) focal plane arrays (FPAs) comprising a Si layer through which light detectable by the FPA reaches photodiodes of the FPA, at least one germanium (Ge) layer including a plurality of distinct photosensitive areas including at least one photosensitive area in each of a plurality of photosensitive photosites, each of the distinct photosensitive areas comprising a plurality of proximate steep structures of Ge having height of at least 0.5 μm and a height-to-width ratio of at least 2, and methods for forming same.

An integrated device, the device including: a first level including a first mono-crystal layer, the first mono-crystal layer including a plurality of single crystal transistors; an overlying oxide disposed on top of the first level; a second level including a second mono-crystal layer, the second level overlaying the oxide, where the second mono-crystal layer includes a plurality of semiconductor devices; a third level overlaying the second level, where the third level includes a plurality of image sensors, where the first level includes a plurality of landing pads, where the second level is bonded to the first level, where the bonded includes an oxide to oxide bond; and an isolation layer disposed between the second mono-crystal layer and the third level.

An image sensor is described having a pixel array. The pixel array has a unit cell that includes visible light photodiodes and an infra-red photodiode. The visible light photodiodes and the infra-red photodiode are coupled to a particular column of the pixel array. The unit cell has a first capacitor coupled to the visible light photodiodes to store charge from each of the visible-light photodiodes. The unit cell has a readout circuit to provide the first capacitor's voltage on the particular column. The unit cell has a second capacitor that is coupled to the infra-red photodiode through a first transfer gate transistor to receive charge from the infra-red photodiode during a time-of-flight exposure. The first capacitor is coupled to the infra-red photodiode through a second transfer gate transistor to receive charge from the infra-red photodiode during the time-of-flight exposure.