A semiconductor device including: a first silicon layer including a first single crystal silicon and a plurality of first transistors; a first metal layer disposed over the first silicon layer; a second metal layer disposed over the first metal layer; a third metal layer disposed over the second metal layer; a second level including a plurality of second transistors, the second level disposed over the third metal layer; a fourth metal layer disposed over the second level; a fifth metal layer disposed over the fourth metal layer, where the fourth metal layer is aligned to first metal layer with a less than 40 nm alignment error; and a via disposed through the second level, where each of the second transistors includes a metal gate, and where a typical thickness of the second metal layer is greater than a typical thickness of the third metal layer by at least 50%.

Germanium-based sensors are disclosed herein. An exemplary germanium-based sensor includes a germanium photodiode and a junction field effect transistor (JFET) formed from a germanium layer disposed on and/or in a silicon substrate. A doped silicon layer, which can be formed by in-situ doping epitaxially grown silicon, is disposed between the germanium layer and the silicon substrate. In embodiments where the germanium layer is on the silicon substrate, the doped silicon layer is disposed between the germanium layer and an oxide layer. The JFET has a doped polysilicon gate, and in some embodiments, a gate diffusion region is disposed in the germanium layer under the doped polysilicon gate. In some embodiments, a pinned photodiode passivation layer is disposed in the germanium layer. In some embodiments, a pair of doped regions in the germanium layer is configured as an e-lens of the germanium-based sensor.

Germanium-based sensors are disclosed herein. An exemplary germanium-based sensor includes a germanium photodiode and a junction field effect transistor (JFET) formed from a germanium layer disposed on and/or in a silicon substrate. A doped silicon layer, which can be formed by in-situ doping epitaxially grown silicon, is disposed between the germanium layer and the silicon substrate. In embodiments where the germanium layer is on the silicon substrate, the doped silicon layer is disposed between the germanium layer and an oxide layer. The JFET has a doped polysilicon gate, and in some embodiments, a gate diffusion region is disposed in the germanium layer under the doped polysilicon gate. In some embodiments, a pinned photodiode passivation layer is disposed in the germanium layer. In some embodiments, a pair of doped regions in the germanium layer is configured as an e-lens of the germanium-based sensor.

A silicon carbide planar MOSFET includes a junction field-effect transistor (JFET) region that extends up to a top planar surface of the substrate. The JFET region includes a central area, which comprises a portion of the drift region that extends vertically to the top planar surface. First and second sidewall areas are disposed on opposite sides of the central area. The central area has a first lateral width and a first doping concentration. The first and second sidewall areas extend vertically to the top planar surface, with each having a second lateral width. The first and second sidewall areas each have a second doping concentration that is greater than the first doping concentration such that, at a zero bias condition, first and second depletion regions respectively extend only within the first and second sidewall areas of the JFET region.

A silicon carbide planar MOSFET includes a junction field-effect transistor (JFET) region that extends up to a top planar surface of the substrate. The JFET region includes a central area, which comprises a portion of the drift region that extends vertically to the top planar surface. First and second sidewall areas are disposed on opposite sides of the central area. The central area has a first lateral width and a first doping concentration. The first and second sidewall areas extend vertically to the top planar surface, with each having a second lateral width. The first and second sidewall areas each have a second doping concentration that is greater than the first doping concentration such that, at a zero bias condition, first and second depletion regions respectively extend only within the first and second sidewall areas of the JFET region.

The present disclosure relates to semiconductor structures and, more particularly, to semiconductor devices with a shared common backside well and methods of manufacture. The structure includes: adjacent gate structures over a semiconductor substrate; a common well in the semiconductor substrate under the adjacent gate structures; a deep trench isolation structure extending through the common well between the adjacent gate structures; and a shared diffusion region between the adjacent gate structures.

A 3D integrated circuit, the circuit including: a first level including a first wafer, the first wafer including a first crystalline substrate, a plurality of first transistors, and first copper interconnecting layers, where the first copper interconnecting layers at least interconnect the plurality of first transistors; and a second level including a second wafer, the second wafer including a second crystalline substrate, a plurality of second transistors, and second copper interconnecting layers, where the second copper interconnecting layers at least interconnect the plurality of second transistors, where the second level is bonded to the first level, where the bonded includes metal to metal bonding, where the bonded includes oxide to oxide bonding, and where at least one of the second transistors include a replacement gate.

A 3D integrated circuit, the circuit including: a first level including a first wafer, the first wafer including a first crystalline substrate, a plurality of first transistors, and first copper interconnecting layers, where the first copper interconnecting layers at least interconnect the plurality of first transistors; and a second level including a second wafer, the second wafer including a second crystalline substrate, a plurality of second transistors, and second copper interconnecting layers, where the second copper interconnecting layers at least interconnect the plurality of second transistors, where the second level is bonded to the first level, where the bonded includes metal to metal bonding, where the bonded includes oxide to oxide bonding, and where at least one of the second transistors include a replacement gate.

Fabricating a regrown GaN p-n junction includes depositing a n-GaN layer on a substrate including n.sup.+-GaN, etching a surface of the n-GaN layer to yield an etched surface, depositing a p-GaN layer on the etched surface, etching a portion of the n-GaN layer and a portion of the p-GaN layer to yield a mesa opposite the substrate, and passivating a portion of the p-GaN layer around an edge of the mesa. The regrown GaN p-n junction is defined at an interface between the n-GaN layer and the p-GaN layer. The regrown GaN p-n junction includes a substrate, a n-GaN layer on the substrate having an etched surface, a p-GaN layer on the etched surface, a mesa defined by an etched portion of the n-GaN layer and an etched portion of the p-GaN layer, and a passivated portion of the p-GaN layer around an edge of the mesa.

An embodiment relates to a semiconductor component, comprising a semiconductor body of a first conductivity type comprising a voltage blocking layer and islands of a second conductivity type on a contact surface and optionally a metal layer on the voltage blocking layer, and a first conductivity type layer comprising the first conductivity type not in contact with a gate dielectric layer or a source layer that is interspersed between the islands of the second conductivity type.