III-nitride materials are generally described herein, including material structures comprising III-nitride material regions and silicon-containing substrates. Certain embodiments are related to gallium nitride materials and material structures comprising gallium nitride material regions and silicon-containing substrates.

A method of manufacturing a super junction MOSFET, which includes a parallel pn layer including a plurality of pn junctions and in which an n-type drift region and a p-type partition region interposed between the pn junctions are alternately arranged and contact each other, a MOS gate structure on the surface of the parallel pn layer, and an n-type buffer layer in contact with an opposite main surface. The impurity concentration of the buffer layer is equal to or less than that of the n-type drift region. At least one of the p-type partition regions in the parallel pn layer is replaced with an n region with a lower impurity concentration than the n-type drift region.

The present invention provides a semiconductor device, including a substrate, two gate structures disposed on a channel region of the substrate, an epitaxial layer disposed in the substrate between two gate structures, a first dislocation disposed in the epitaxial layer, wherein the profile of the first dislocation has at least two non-parallel slanting lines, and a second dislocation disposed adjacent to a top surface of the epitaxial layer, and the profile of the second dislocation has at least two non-parallel slanting lines.

A semiconductor structure is provided that includes a plurality of suspended and stacked nanosheets of semiconductor channel material located above a pillar of a sacrificial III-V compound semiconductor material. Each semiconductor channel material comprises a semiconductor material that is substantially lattice matched to, but different from, the sacrificial III-V compound semiconductor material, and each suspended and stacked nanosheets of semiconductor channel material has a chevron shape. A functional gate structure can be formed around each suspended and stacked nanosheet of semiconductor channel material.

A method of manufacturing a semiconductor device includes: forming a lattice defect layer in a substrate having a front surface region where a bipolar element of a pn junction type is formed and a rear surface region opposing the front surface region, the lattice defect layer being formed by injecting a charged particle to a first region in the rear surface region of the substrate; forming a laminated region, in which a first conductivity type impurity region and a second conductivity type impurity region are sequentially laminated from a rear surface side of the substrate toward the first region, in a second region in the rear surface region of the substrate, the first region being positioned deeper than the second region from a rear surface of the substrate; and selectively activating the laminated region by laser annealing after the formation of the laminated region and the lattice defect layer.

A semiconductor device according to the present invention includes a semiconductor substrate, having an emitter layer of a first conductivity type, a collector layer of a second conductivity type and a drift layer of the first conductivity type sandwiched therebetween, the emitter layer disposed at a front surface side of the semiconductor substrate and the collector layer disposed at a rear surface side of the semiconductor substrate, a base layer of the second conductivity type between the drift layer and the emitter layer, a buffer layer of the first conductivity type between the collector layer and the drift layer, the buffer layer having an impurity concentration higher than that of the drift layer, and having an impurity concentration profile with two peaks in regard to a depth direction from the rear surface of the semiconductor substrate, and a defect layer, formed in the drift layer and having an impurity concentration profile with a half-value width of not more than 2 m in regard to the depth direction from the rear surface of the semiconductor substrate.

A crystalline base substrate including a first semiconductor material and having a main surface is provided. The base substrate is processed so as to damage a lattice structure of the base substrate in a first region that extends to the main surface without damaging a lattice structure of the base substrate in second regions that are adjacent to the first region. A first semiconductor layer of a second semiconductor material is formed on a portion of the main surface that includes the first and second regions. A third region of the first semiconductor layer covers the first region of the base substrate, and a fourth region of the first semiconductor layer covers the second region of the base substrate. The third region has a crystalline structure that is disorganized relative to a crystalline structure of the fourth region. The first and second semiconductor materials have different coefficients of thermal expansion.

A vertical power component includes a silicon substrate of a first conductivity type with a well of the second conductivity type on a lower surface of the substrate. The first well is bordered at a component periphery with an insulating porous silicon ring. An upper surface of the porous silicon ring is only in contact with the substrate of the first conductivity type. The insulating porous silicon ring penetrates into the substrate down to a depth greater than a thickness of the well. The porous silicon ring is produced by forming a doped well in a first surface of a doped substrate, placing that first surface of the substrate into an electrolytic bath, and circulating a current between an opposite second surface of the substrate and the electrolytic bath.

An alternating stack of insulating layers and sacrificial material layers is formed over a substrate. Memory openings are formed through the alternating stack to the substrate. After formation of memory film layers, a sacrificial cover material layer can be employed to protect the tunneling dielectric layer during formation of a bottom opening in the memory film layers. An amorphous semiconductor material layer can be deposited and optionally annealed in an ambient including argon and/or deuterium to form a semiconductor channel layer having a thickness less than 5 nm and surface roughness less than 10% of the thickness. Alternately or additionally, at least one interfacial layer can be employed on either side of the amorphous semiconductor material layer to reduce surface roughness of the semiconductor channel. The ultrathin channel can have enhanced mobility due to quantum confinement effects.

A semiconductor structure containing a high mobility semiconductor channel material, i.e., a III-V semiconductor material, and asymmetrical source/drain regions located on the sidewalls of the high mobility semiconductor channel material is provided. The asymmetrical source/drain regions can aid in improving performance of the resultant device. The source region contains a source-side epitaxial doped semiconductor material, while the drain region contains a drain-side epitaxial doped semiconductor material and an underlying portion of the high mobility semiconductor channel material.