An opto-electronic High Electron Mobility Transistor (HEMT) may include a current channel including a two-dimensional electron gas (2DEG). The opto-electronic HEMT may further include a photoelectric bipolar transistor embedded within at least one of a source and a drain of the HEMT, the photoelectric bipolar transistor being in series with the current channel of the HEMT.

An opto-electronic High Electron Mobility Transistor (HEMT) may include a current channel including a two-dimensional electron gas (2DEG). The opto-electronic HEMT may further include a photoelectric bipolar transistor embedded within at least one of a source and a drain of the HEMT, the photoelectric bipolar transistor being in series with the current channel of the HEMT.

An opto-electronic High Electron Mobility Transistor (HEMT) may include a current channel including a two-dimensional electron gas (2DEG). The opto-electronic HEMT may further include a photoelectric bipolar transistor embedded within at least one of a source and a drain of the HEMT, the photoelectric bipolar transistor being in series with the current channel of the HEMT.

An imager having a pixel cell having an associated strained silicon layer. The strained silicon layer increases charge transfer efficiency, decreases image lag, and improves blue response in imaging devices.

An infrared detector and a method for manufacturing it are disclosed. The infrared photo-detector contains a photo absorber layer responsive to infrared light, a first barrier layer disposed on the absorber layer, wherein the first barrier layer substantially comprises AlSb, a second barrier layer disposed on the first barrier layer, wherein the second barrier layer substantially comprises Al.sub.xGa.sub.1-xSb and a contact layer disposed on the second barrier layer.

An infrared detector and a method for manufacturing it are disclosed. The infrared photo-detector contains a photo absorber layer responsive to infrared light, a first barrier layer disposed on the absorber layer, wherein the first barrier layer substantially comprises AlSb, a second barrier layer disposed on the first barrier layer, wherein the second barrier layer substantially comprises Al.sub.xGa.sub.1-xSb and a contact layer disposed on the second barrier layer.

A multi-color light detector includes a first photodiode. The light detector further includes a second photodiode stacked on the first photodiode and defining a via. The light detector further includes a first conductor extending through the via, contacting the first photodiode, and designed to transmit a first signal corresponding to a first light detected by the first photodiode. The light detector further includes a second conductor contacting the second photodiode and designed to transmit a second signal corresponding to a second light detected by the second photodiode.

A multi-color light detector includes a first photodiode. The light detector further includes a second photodiode stacked on the first photodiode and defining a via. The light detector further includes a first conductor extending through the via, contacting the first photodiode, and designed to transmit a first signal corresponding to a first light detected by the first photodiode. The light detector further includes a second conductor contacting the second photodiode and designed to transmit a second signal corresponding to a second light detected by the second photodiode.

Disclosed is an active photonic device having a Darlington configuration with a substrate and a collector layer that is over the substrate. The collector layer includes an inner collector region. An outer collector region substantially surrounds the inner collector region and is spaced apart from the inner collector region. A base layer is over the collector layer. A first outer base region and a second outer base region substantially surround the inner base region and are spaced apart from the inner base region and each other. An emitter layer is over the base layer. The emitter layer includes an inner emitter region that is ring-shaped and resides over and extends substantially around an outer periphery of the inner base region. A first outer emitter region and a second outer emitter region substantially surround the inner emitter region and are spaced apart from the inner emitter region and each other.

Methods and devices for an avalanche photo-transistor. In one aspect, an avalanche photo-transistor includes a detection region configured to absorb light incident on a first surface of the detection region and generate one or more charge carriers in response, a first terminal in electrical contact with the detection region and configured to bias the detection region, an interim doping region, a second terminal in electrical contact with the interim doping region and configured to bias the interim doping region, a multiplication region configured to receive the one or more charge carriers flowing from the interim doping region and generate one or more additional charge carriers in response, a third terminal in electrical contact with the multiplication region and configured to bias the multiplication region, wherein the interim doping region is located in between the detection region and the multiplication region.