Examples of the various techniques introduced here include, but not limited to, a mesa height adjustment approach during shallow trench isolation formation, a transistor via first approach, and a multiple absorption layer approach. As described further below, the techniques introduced herein include a variety of aspects that can individually and/or collectively resolve or mitigate one or more traditional limitations involved with manufacturing PDs and transistors on the same substrate, such as above discussed reliability, performance, and process temperature issues.

An integrated circuit includes a substrate material that includes an epitaxial layer, wherein the substrate material and the epitaxial layer form a first semiconductor material with the epitaxial layer having a first conductivity type. At least one nanowire comprising a second semiconductor material having a second conductivity type doped differently than the first conductivity type of the first semiconductor material forms a junction crossing region with the first semiconductor material. The nanowire and the first semiconductor material form an avalanche photodiode (APD) in the junction crossing region to enable single photon detection. In an alternative configuration, the APD is formed as a p-i-n crossing region where n represents an n-type material, i represents an intrinsic layer, and p represents a p-type material.

Approaches for silicon photonics integration are provided. A method includes: forming at least one encapsulating layer over and around a photodetector; thermally crystallizing the photodetector material after the forming the at least one encapsulating layer; and after the thermally crystallizing the photodetector material, forming a conformal sealing layer on the at least one encapsulating layer and over at least one device. The conformal sealing layer is configured to seal a crack in the at least one encapsulating layer. The photodetector and the at least one device are on a same substrate. The at least one device includes a complementary metal oxide semiconductor device or a passive photonics device.

Techniques for enhancing the absorption of photons in semiconductors with the use of microstructures are described. The microstructures, such as holes, effectively increase the absorption of the photons. Using microstructures for absorption enhancement for silicon photodiodes and silicon avalanche photodiodes can result in bandwidths in excess of 10 Gb/s at photons with wavelengths of 850 nm, and with quantum efficiencies of approximately 90% or more. Their thickness dimensions allow them to be conveniently integrated on the same Si chip with CMOS, BiCMOS, and other electronics, with resulting packaging benefits and reduced capacitance and thus higher speeds.

An integration method of fabricating optical sensor device and thin film transistor device includes the follow steps. A substrate is provided, and a gate electrode and a bottom electrode are formed on the substrate. A first insulating layer is formed on the gate electrode and the bottom electrode, and the first insulating layer at least partially exposes the bottom electrode. An optical sensing pattern is formed on the bottom electrode. A patterned transparent semiconductor layer is formed on the first insulating layer, wherein the patterned transparent semiconductor layer includes a first transparent semiconductor pattern covering the gate electrode, and a second transparent semiconductor pattern covering the optical sensing pattern. A source electrode and a drain electrode are formed on the first transparent semiconductor pattern. A modification process including introducing at least one gas is performed on the second transparent semiconductor pattern to transfer the second transparent semiconductor pattern into a conductive transparent top electrode.

An optical sensor for detecting chemical, biochemical or biological substances includes a laser and a semiconductor chip. The sensor includes at least one photodetector and at least one high-contrast grating that are monolithically integrated in the semiconductor chip. The high-contrast grating is configured to optically couple radiation emitted by the laser into the photodetector. The coupling behavior of the high-contrast grating depends on the optical properties of external substances that are brought near to or in contact with the high-contrast grating.

A light sensing device includes a substrate, a semiconductor device layer, a metal and insulation material stacked structure, and a light absorption layer. The substrate has a recessed portion. The semiconductor device layer is located on the substrate. The metal and insulation material stacked structure is located on the semiconductor device layer and includes a first interconnect structure, a second interconnect structure surrounding the first interconnect structure, and a device conductive line. The light absorption layer is located on the metal and insulation material stacked structure. The first interconnect structure is located between the light absorption layer and the semiconductor device layer, such that the light absorption layer and the semiconductor device layer located at different levels can be connected to each other and exchange heat.

Disclosed is an avalanche photodiode using a silicon nanowire, including a first silicon nanowire formed of silicon (Si), a first conductive region formed by doping one surface of the first silicon nanowire with a first dopant, and a second conductive region formed by doping one surface of the first silicon nanowire with a second dopant having a conductive type different from that of the first dopant so as to be arranged continuously in a longitudinal direction from the first conductive region, wherein, when the magnitude of a reverse voltage applied to both ends of the first silicon nanowire is equal to or greater than a preset breakdown voltage, avalanche multiplication of inner current occurs due to the incidence of light from the outside.

According to example embodiments, an electronic device includes channel layer including a graphene layer electrically contacting a quantum dot layer including a plurality of quantum dots, a first electrode and a second electrode electrically connected to the channel layer, respectively, and a gate electrode configured to control an electric current between the first electrode and the second electrode via the channel layer. A gate insulating layer may be between the gate electrode and the channel layer.

A Dual-wavelength hybrid (DWH) device includes an n-type ohmic contact layer, cathode and anode terminal electrodes, first and second injector terminal electrodes, p-type and n-type modulation doped QW structures, and first through sixth ion implant regions. The first injector terminal electrode is formed on the third ion implant region that contacts the p-type modulation doped QW structure and the second injector terminal electrode is formed on the fourth ion implant region that contacts the n-type modulation doped QW structure. The DWH device operates in at least one of a vertical cavity mode and a whispering gallery mode. In the vertical cavity mode, the DWH device converts an in-plane optical mode signal to a vertical optical mode signal, whereas in the whispering gallery mode the DWH device converts a vertical optical mode signal to an in-plane optical mode signal.