An integrated circuit structure comprising a substrate having an upper surface; a gallium nitride layer disposed on the upper surface of the substrate; and a photoconductive semiconductor switch laterally disposed alongside a transistor on the gallium nitride layer integrated into the integrated circuit structure wherein a regrown gallium nitride material is disposed on the photoconductive semiconductor switch and operatively coupled with the wafer.

An apparatus including a semiconductor substrate; an absorption layer coupled to the semiconductor substrate, the absorption layer including a photodiode region configured to absorb photons and to generate photo-carriers from the absorbed photons; one or more first switches controlled by a first control signal, the one or more first switches configured to collect at least a portion of the photo-carriers based on the first control signal; and one or more second switches controlled by a second control signal, the one or more second switches configured to collect at least a portion of the photo-carriers based on the second control signal, where the second control signal is different from the first control signal.

Structures including a photodetector and methods of fabricating such structures. The photodetector is positioned over the top surface of the substrate. The photodetector includes a portion of a semiconductor layer comprised of a semiconductor alloy, a p-type doped region in the portion of the semiconductor layer, and an n-type doped region in the portion of the semiconductor layer. The p-type doped region and the n-type doped region converge along a p-n junction. The portion of the semiconductor layer has a first side and a second side opposite from the first side. The semiconductor alloy has a composition that is laterally graded from the first side to the second side of the portion of the semiconductor layer.

Structures including a photodetector and methods of fabricating such structures. The photodetector is positioned over the top surface of the substrate. The photodetector includes a portion of a semiconductor layer comprised of a semiconductor alloy, a p-type doped region in the portion of the semiconductor layer, and an n-type doped region in the portion of the semiconductor layer. The p-type doped region and the n-type doped region converge along a p-n junction. The portion of the semiconductor layer has a first side and a second side opposite from the first side. The semiconductor alloy has a composition that is laterally graded from the first side to the second side of the portion of the semiconductor layer.

The present disclosure relates a method of forming an integrated chip structure. The method includes etching a base substrate to form a recess defined by one or more interior surfaces of the base substrate. A doped epitaxial layer is formed along the one or more interior surfaces of the base substrate, and an epitaxial material is formed on horizontally and vertically extending surfaces of the doped epitaxial layer. A first doped photodiode region is formed within the epitaxial material and a second doped photodiode region is formed within the epitaxial material. The first doped photodiode region has a first doping type and the second doped photodiode region has a second doping type.

The present disclosure relates to a photodiode device, which overcomes the drawbacks of conventional devices like increased dark currents. The photodiode device includes a semiconductor substrate, at least one doped well of a first type of electric conductivity at a main surface of the substrate and at least one doped region of a second type of electric conductivity being adjacent to the doped well. The at least one doped well and the at least one doped region are electrically contactable. On a portion of an upper surface of the doped well a protection structure is arranged. The protection structure protects the upper surface of the underlying doped well from an etching process for removing a spacer layer.

The present disclosure relates to a photodiode device, which overcomes the drawbacks of conventional devices like increased dark currents. The photodiode device includes a semiconductor substrate, at least one doped well of a first type of electric conductivity at a main surface of the substrate and at least one doped region of a second type of electric conductivity being adjacent to the doped well. The at least one doped well and the at least one doped region are electrically contactable. On a portion of an upper surface of the doped well a protection structure is arranged. The protection structure protects the upper surface of the underlying doped well from an etching process for removing a spacer layer.

An optical sensor includes a semiconductor substrate having a first conductive type. The optical sensor further includes a photodiode disposed on the semiconductor substrate and a metal layer. The photodiode includes a first semiconductor layer having the first conductive type and a second semiconductor layer, formed on the first semiconductor layer, including a plurality of cathodes having a second conductive type. The first semiconductor layer is configured to collect photocurrent upon reception of incident light. The cathodes are configured to be electrically connected to the first semiconductor layer and the second semiconductor layer is configured to, based on the collected photocurrent, to track the incident light. The metal layer further includes a pinhole configured to collimate the incident light, and the plurality of cathodes form a rotational symmetry of order n with respect to an axis of the pinhole.

An optical sensor includes a semiconductor substrate having a first conductive type. The optical sensor further includes a photodiode disposed on the semiconductor substrate and a metal layer. The photodiode includes a first semiconductor layer having the first conductive type and a second semiconductor layer, formed on the first semiconductor layer, including a plurality of cathodes having a second conductive type. The first semiconductor layer is configured to collect photocurrent upon reception of incident light. The cathodes are configured to be electrically connected to the first semiconductor layer and the second semiconductor layer is configured to, based on the collected photocurrent, to track the incident light. The metal layer further includes a pinhole configured to collimate the incident light, and the plurality of cathodes form a rotational symmetry of order n with respect to an axis of the pinhole.

A circuit, including: a photodetector including a first readout terminal and a second readout terminal different than the first readout terminal; a first readout circuit coupled with the first readout terminal and configured to output a first readout voltage; a second readout circuit coupled with the second readout terminal and configured to output a second readout voltage; and a common-mode analog-to-digital converter (ADC) including: a first input terminal coupled with a first voltage source; a second input terminal coupled with a common-mode generator, the common-mode generator configured to receive the first readout voltage and the second readout voltage, and to generate a common-mode voltage between the first and second readout voltages; and a first output terminal configured to output a first output signal corresponding to a magnitude of a current generated by the photodetector.