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.

A method for preparing an avalanche photodiode includes preparing a mesa on a wafer, growing a sacrificial layer on an upper surface of the wafer and a side surface of the mesa, removing the sacrificial layer in an ohmic contact electrode region of the wafer, preparing an ohmic contact electrode in the ohmic contact electrode region of the wafer, removing the sacrificial layer in a non-mesa region of the wafer, growing a passivation layer on the upper surface of the wafer and the side surface of the mesa, removing the passivation layer on the upper surface of the mesa of the wafer and the passivation layer in the non-mesa region of the wafer corresponding to the ohmic contact electrode region, and removing the sacrificial layer on the upper surface of the mesa of the wafer.

An optical semiconductor element having a mesa portion includes a substrate and semiconductor layers on the substrate. The optical semiconductor element further includes a first contact electrode, a second contact electrode on the semiconductor layer, first and second lead-out wires connected to the first and second contact electrodes, respectively, and an insulating film covering at least an upper surface of the semiconductor layer and the second contact electrode. The second lead-out wire is connected to the second contact electrode in an opening of the insulating film. An outer peripheral end of the second contact electrode in at least a portion where the second contact electrode and the second lead-out wire are connected is above and outside an outer peripheral end of a connection portion with the semiconductor layer, and an inner peripheral end is above and inside an inner peripheral end of the connection portion with the semiconductor layer.

Technology for light detection and ranging (LIDAR) sensor can include an optical signal source, an optical modulation array and optical detector on the same integrated circuit (IC) chip, multi-chip module (MCM) or similar solid-state package.

A photodiode has a substrate. A mesa structure is formed on the substrate, wherein the mesa structure has an n region containing an n type dopant formed on the substrate, an intermediate region positioned on the n region and a p region formed on the intermediate region and containing a p type dopant. A contact is formed on a top surface of the mesa and attached to the p region. The contact is formed around an outer perimeter of the mesa. The mesa has a diameter of 30 um or less.

A solid state imaging apparatus includes an insulation structure formed of an insulation substance penetrating through at least a silicon layer at a light receiving surface side, the insulation structure having a forward tapered shape where a top diameter at an upper portion of the light receiving surface side of the silicon layer is greater than a bottom diameter at a bottom portion of the silicon layer. Also, there are provided a method of producing the solid state imaging apparatus and an electronic device including the solid state imaging apparatus.

Provided is a single photon detector. The single photo detector includes a substrate of a first conductivity type, a light absorption layer on the substrate, a grading layer and an electric field buffer layer sequentially stacked on the light absorption layer, an impurity region of a second conductivity type disposed in the electric field buffer layer and opposite the first conductivity type, a first electrode disposed on the electric field buffer layer and electrically connected to the impurity region, a reflective layer disposed between the light absorption layer and the substrate, and a second electrode disposed below the substrate and electrically connected to the substrate.

An X-ray detector based on silicon carbide single crystal as well as its preparation method. The detector mainly includes: high resistivity silicon carbide single crystal, high electron concentration n-type silicon carbide layer, low electron concentration n-type silicon carbide layer, high hole concentration p-type silicon carbide layer, low hole concentration p-type silicon carbide layer, silicon dioxide protection layer, p-type silicon carbide ohmic contact electrode, n-type silicon carbide ohmic contact electrode, and gold lead electrode. The invention provides an effective and simple process manufacturing technology, solves the preparation problem of silicon carbide-based high-energy X-ray detector, and realizes the development of a new silicon carbide radiation detector.

A solid state imaging apparatus includes an insulation structure formed of an insulation substance penetrating through at least a silicon layer at a light receiving surface side, the insulation structure having a forward tapered shape where a top diameter at an upper portion of the light receiving surface side of the silicon layer is greater than a bottom diameter at a bottom portion of the silicon layer. Also, there are provided a method of producing the solid state imaging apparatus and an electronic device including the solid state imaging apparatus.

Photonically integrated normal incidence photodetectors (NIPDs) and associated in-plane waveguide structures optically coupled to the NIPDs can be configured to allow for both in-plane and normal-incidence detection. In photonic circuits with light-generation capabilities, such as integrated optical transceivers, the ability of the NIPDs to detect in-plane light is used, in accordance with some embodiments, to provide self-test functionality.