Abstract: A method for fabricating an image sensor comprises: forming an array of sensor elements on a sensor-wafer substrate; forming a readout circuit on the sensor-wafer substrate; forming a plurality of signal lines between the array of sensor elements and the readout circuit; forming a solid-state cooler between the array of sensor elements and the readout circuit; bonding a carrier-wafer substrate to an epitaxial structure of the sensor-wafer substrate; etching the carrier-wafer substrate in the thermal-barrier zone to form a carrier-wafer trench between the array of sensor elements and the readout circuit; reducing the thickness of the sensor-wafer substrate; and etching the sensor-wafer substrate in the thermal-barrier zone to form a sensor-wafer trench between the array of sensor elements and the readout circuit.

Abstract: One aspect of this disclosure relates to a sensor element comprising first and second epitaxial layers and one or more electrode structures. The first epitaxial layer includes a base of p-doped silicon and a zone of n-doped silicon arranged within the base, the zone being aligned to an epitaxy side of the first epitaxial layer. The second epitaxial layer is arranged on the epitaxy side of the first epitaxial layer and comprises a semiconductor having a narrower bandgap than silicon. The one or more electrode structures are arranged on the epitaxy side of the first epitaxial layer, adjacent the second epitaxial layer.

Abstract: An image sensor comprises an array of sensor elements, each responsive to incident photon flux, and a readout circuit coupled electronically to the array of sensor elements and configured to release an electronic signal varying in dependence on the incident photon flux. A thermal-barrier zone separates the array of sensor elements from the readout circuit, and a solid-state cooler is coupled thermally to the array of sensor elements.

Abstract: An example imaging sensor comprises a bulk silicon substrate and a pixel array. The pixel array comprises an active pixel region including an active pixel subarray, an optical black pixel region including an optical black pixel subarray, and an optical black dummy pixel region including an optical black dummy pixel subarray, the optical black dummy pixel region positioned between the active pixel region and the optical black pixel region. A near-infrared absorber is positioned between the active pixel region and the optical black pixel region, the near-infrared absorber comprising a material having a higher near-infrared absorption coefficient than that of silicon.

Abstract: An example imaging sensor comprises a bulk silicon substrate and a pixel array. The pixel array comprises an active pixel region including an active pixel subarray, an optical black pixel region including an optical black pixel subarray, and an optical black dummy pixel region including an optical black dummy pixel subarray, the optical black dummy pixel region positioned between the active pixel region and the optical black pixel region. A near-infrared absorber is positioned between the active pixel region and the optical black pixel region, the near-infrared absorber comprising a material having a higher near-infrared absorption coefficient than that of silicon.

Abstract: A time-of-flight image sensor is disclosed. The time-of-flight image sensor includes an array of pixels. Each pixel of the array of pixels includes a first photogate, a second photogate adjacent the first photogate, an isolation barrier intermediate the first photogate and the second photogate, and an in-pixel ground node intermediate the first photogate and the second photogate.

Abstract: An image sensor comprises an array of sensor elements, each responsive to incident photon flux, and a readout circuit coupled electronically to the array of sensor elements and configured to release an electronic signal varying in dependence on the incident photon flux. A thermal-barrier zone separates the array of sensor elements from the readout circuit, and a solid-state cooler is coupled thermally to the array of sensor elements.

Abstract: Examples are disclosed that relate to the use of an always-depleted photodiode in a ToF depth image sensor. One example provides a method of operating a pixel of a depth image sensor, the method comprising receiving photons in a photocharge generation region of the pixel, the photocharge generation region of the pixel comprising an always-depleted photodiode formed by a doped first region comprising one of p-doping or n-doping and a more lightly-doped second region comprising the other of p-doping or n-doping. The method further comprises, during an integration phase, energizing a clock gate for a pixel tap, thereby directing photocharge generated in the photocharge generation region to an in-pixel storage comprising a capacitor, and in a readout phase, reading charge out from the in-pixel storage.

Abstract: An example imaging sensor comprises a bulk silicon substrate and a pixel array. The pixel array comprises an active pixel region including an active pixel subarray, an optical black pixel region including an optical black pixel subarray, and an optical black dummy pixel region including an optical black dummy pixel subarray, the optical black dummy pixel region positioned between the active pixel region and the optical black pixel region. A near-infrared absorber is positioned between the active pixel region and the optical black pixel region, the near-infrared absorber comprising a material having a higher near-infrared absorption coefficient than that of silicon.

Abstract: Examples are disclosed that relate to the use of an always-depleted photodiode in a ToF depth image sensor. One example provides a method of operating a pixel of a depth image sensor, the method comprising receiving photons in a photocharge generation region of the pixel, the photocharge generation region of the pixel comprising an always-depleted photodiode formed by a doped first region comprising one of p-doping or n-doping and a more lightly-doped second region comprising the other of p-doping or n-doping. The method further comprises, during an integration phase, energizing a clock gate for a pixel tap, thereby directing photocharge generated in the photocharge generation region to an in-pixel storage comprising a capacitor, and in a readout phase, reading charge out from the in-pixel storage.

Abstract: A time-of-flight image sensor is disclosed. The time-of-flight image sensor includes an array of pixels. Each pixel of the array of pixels includes a first photogate, a second photogate adjacent the first photogate, an isolation barrier intermediate the first photogate and the second photogate, and an in-pixel ground node intermediate the first photogate and the second photogate.

Abstract: An imaging sensor array comprises an epitaxial germanium layer disposed on a silicon layer, and an electrically biased photoelectron collector arranged on the silicon layer, on a side opposite the germanium layer.

Abstract: An imaging sensor array comprises an epitaxial germanium layer disposed on a silicon layer, and an electrically biased photoelectron collector arranged on the silicon layer, on a side opposite the germanium layer.