There is provided a photodiode array including a semiconducting substrate and a plurality of photodiodes that are disposed at a surface of the substrate. Each photodiode is laterally spaced apart from neighboring photodiodes by a lateral substrate surface region. An optical interface surface of the substrate is arranged for accepting external input radiation. A plurality of electrically conducting fuses are disposed on the substrate surface. Each fuse is connected to a photodiode in the plurality of photodiodes. Each fuse is disposed at a lateral substrate surface region that is spaced apart from neighboring photodiodes in the plurality of photodiodes.

An optoelectronic device comprising a mesa structure including: a first and a second semiconductor portions forming a p-n junction, a first electrode electrically connected to the first portion which is arranged between the second portion and the first electrode, the device further comprising: a second electrode electrically connected to the second portion, an element able to ionize dopants of the first and/or second semiconductor portion through generating an electric field in the first and/or second semiconductor portion and overlaying at least one part of the side flanks of at least one part of the first and/or second semiconductor portion and of at least one part of a space charge zone formed by the first and second semiconductor portions, upper faces of the first electrode and of the second electrode form a substantially planar continuous surface.

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.

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 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 ultraviolet-erasable nonvolatile semiconductor device has a protective film comprised of a silicon nitride film on which is laminated a silicon oxynitride film. The silicon nitride film has a thickness of 1000 or more and 2000 or less and the silicon oxynitride film has a thickness of about 7000 or more. The silicon nitride film and the silicon oxynitride film cooperate to prevent moisture from penetrating into the ultraviolet-erasable nonvolatile semiconductor device. The thickness of the silicon nitride film is set so that the time for erasing data in a nonvolatile semiconductor storage element through irradiation with ultraviolet rays is not increased.

A method of protecting a CMOS device within an integrated photonic semiconductor structure is provided. The method may include depositing a conformal layer of germanium over the CMOS device and an adjacent area to the CMOS device, depositing a conformal layer of dielectric hardmask over the germanium, and forming, using a mask level, a patterned layer of photoresist for covering the CMOS device and a photonic device formation region within the adjacent area. Openings are etched into areas of the deposited layer of silicon nitride not covered by the patterned photoresist, such that the areas are adjacent to the photonic device formation region. The germanium material is then etched from the conformal layer of germanium at a location underlying the etched openings for forming the photonic device at the photonic device formation region. The conformal layer of germanium deposited over the CMOS device protects the CMOS device.

Disclosed are a method of forming a photodetector and a photodetector structure. In the method, a polycrystalline or amorphous light-absorbing layer is formed on a dielectric layer such that it is in contact with a monocrystalline semiconductor core of an optical waveguide. The light-absorbing layer is then encapsulated in one or more strain-relief layers and a rapid melting growth (RMG) process is performed to crystallize the light-absorbing layer. The strain-relief layer(s) are tuned for controlled strain relief so that, during the RMG process, the light-absorbing layer remains crack-free. The strain-relief layer(s) are then removed and an encapsulation layer is formed over the light-absorbing layer (e.g., filling in surface pits that developed during the RMG process). Subsequently, dopants are implanted through the encapsulation layer to form diffusion regions for PIN diode(s). Since the encapsulation layer is relatively thin, desired dopant profiles can be achieved within the diffusion regions.

An optical sensor including a semiconductor substrate; a first light absorption region formed in the semiconductor substrate, the first light absorption region configured to absorb photons at a first wavelength range and to generate photo-carriers from the absorbed photons; a second light absorption region formed on the first light absorption region, the second light absorption region configured to absorb photons at a second wavelength range and to generate photo-carriers from the absorbed photons; and a sensor control signal coupled to the second light absorption region, the sensor control signal configured to provide at least a first control level and a second control level.

Guided-wave photodetectors based on absorption of infrared photons by mid-bandgap states in non-crystal semiconductors. In one example, a resonant guided-wave photodetector is fabricated based on a polysilicon layer used for the transistor gate in a SOI CMOS process without any change to the foundry process flow (zero-change CMOS). Mid-bandgap defect states in the polysilicon absorb infrared photons. Through a combination of doping mask layers, a lateral p-n junction is formed in the polysilicon, and a bias voltage applied across the junction creates a sufficiently strong electric field to enable efficient photo-generated carrier extraction and high-speed operation. An example device has a responsivity of more than 0.14 A/W from 1300 to 1600 nm, a 10 GHz bandwidth, and 80 nA dark current at 15 V reverse bias.