A vertical transistor and the fabrication method. The transistor comprises a first surface and a second surface that is opposite to the first surface. A drift region of the first doping type, this drift region is located between the first surface and the second surface; at least one source region of the first doping type and the source region being located between the drift region and the first surface, with a first dielectric layer located between adjacent source regions; at least one drain region with said first doping type and said drain region being located between said drift region and said second surface, a gate being provided between adjacent drain regions. Said gate includes a gate electrode and a gate dielectric layer disposed between said gate electrode and said drift region, and the second dielectric layer being positioned between said gate electrode and said second surface.

Some embodiments include a transistor having a first electrically conductive gate portion along a first segment of a channel region and a second electrically conductive gate portion along a second segment of the channel region. The second electrically conductive gate portion is a different composition than the first electrically conductive gate portion. Some embodiments include a method of forming a semiconductor construction. First semiconductor material and metal-containing material are formed over a NAND string. An opening is formed through the metal-containing material and the first semiconductor material, and is lined with gate dielectric. Second semiconductor material is provided within the opening to form a channel region of a transistor. The transistor is a select device electrically coupled to the NAND string.

Methods, systems, and devices are disclosed for implementing high power circuits and semiconductor devices. In one aspect, a method for fabricating a silicon carbide semiconductor device includes forming a thin epitaxial layer of a nitrogen doped SiC material on a SiC epitaxial layer formed on a SiC substrate, and thermally growing an oxide layer to form an insulator material on the nitrogen doped SiC epitaxial layer, in which the thermally grown oxide layer results in at least partially consuming the nitrogen doped SiC epitaxial layer in the oxide layer to produce an interface including nitrogen between the SiC epitaxial layer and the oxide layer.

A method of forming a transistor device includes providing a drift layer having a first conductivity type, forming a first region in the drift layer, the first region having a second conductivity type that is opposite the first conductivity type, forming a body layer on the drift layer including the first region, forming a source layer on the body layer, forming a trench in the source layer and the body layer above the first region and extending into the first region, forming a gate insulator on the inner sidewall of the trench, and forming a gate contact on the gate insulator.

A semiconductor device structure according to some embodiments includes a silicon carbide substrate having a first conductivity type, a silicon carbide drift layer having the first conductivity type on the silicon carbide substrate and having an upper surface opposite the silicon carbide substrate, and a buried junction structure in the silicon carbide drift layer. The buried junction structure has a second conductivity type opposite the first conductivity type and has a junction depth that is greater than about one micron.

Provided is a crystalline multilayer structure having good semiconductor properties. In particular, the crystalline multilayer structure has good electrical properties as follows: the controllability of conductivity is good; and vertical conduction is possible. A crystalline multilayer structure includes a metal layer containing a uniaxially oriented metal as a major component and a semiconductor layer disposed directly on the metal layer or with another layer therebetween and containing a crystalline oxide semiconductor as a major component. The crystalline oxide semiconductor contains one or more metals selected from gallium, indium, and aluminum and is uniaxially oriented.

Methods, systems, and devices are disclosed for implementing high power circuits and semiconductor devices. In one aspect, a method for fabricating a silicon carbide semiconductor device includes forming a thin epitaxial layer of a nitrogen doped SiC material on a SiC epitaxial layer formed on a SiC substrate, and thermally growing an oxide layer to form an insulator material on the nitrogen doped SiC epitaxial layer, in which the thermally grown oxide layer results in at least partially consuming the nitrogen doped SiC epitaxial layer in the oxide layer to produce an interface including nitrogen between the SiC epitaxial layer and the oxide layer.

A vertical, fin-based field effect transistor (FinFET) device includes an array of individual FinFET cells. The array includes a plurality of rows and columns of separated fins. Each of the separated fins is in electrical communication with a source contact. The vertical FinFET device also includes one or more rows of first inactive fins disposed on a first set of sides of the array of individual FinFET cells, one or more columns of second inactive fins disposed on a second set of sides of the array of individual FinFET cells, and a gate region surrounding the individual FinFET cells of the array of individual FinFET cells, the first inactive fins, and the second inactive fins.

A semiconductor device includes a first conductive part, a second conductive part, a third conductive part, a first insulating part, and a semiconductor part of a first conductivity type. The second conductive part is separated from the first conductive part in a first direction. The third conductive part arranged with a portion of the second conductive part in a second direction crossing the first direction. The first insulating part includes a first insulating region located between the third conductive part and the portion of the second conductive part. The semiconductor part includes a first semiconductor region and a second semiconductor region. The first semiconductor region is located between the first conductive part and the second conductive part. The second semiconductor region is located between the first insulating region and the portion of the second conductive part. The second semiconductor region has a Schottky junction with the second conductive part.

A transistor device having reduced electrical field at the gate oxide interface is disclosed. In one embodiment, the transistor device comprises a gate, a source, and a drain, wherein the gate is at least partially in contact with a gate oxide. The transistor device has a P+ region within a JFET region of the transistor device in order to reduce an electrical field on the gate oxide.