A metal oxide semiconductor field effect transistor and a method for manufacturing the same are provided. The metal oxide semiconductor field effect transistor includes a substrate structure, doped regions, an oxide layer structure, semiconductor layer structures, a dielectric layer structure, and a metal structure. The substrate structure includes a base layer and an epitaxial layer. The epitaxial layer forms a plurality of trenches along a first direction. Any two adjacent trenches form a pitch therebetween, and the pitches formed between the trenches are increased along the first direction. The doped regions are formed at bottoms of the trenches. The oxide layer structure is formed on inner walls of the trenches and a surface of the epitaxial layer. The semiconductor layer structures are respectively formed in the trenches. The dielectric layer structure is formed on the oxide layer structure. The metal structure is formed on the dielectric layer structure.

A semiconductor device having a vertical drain extended MOS transistor may be formed by forming deep trench structures to define vertical drift regions of the transistor, so that each vertical drift region is bounded on at least two opposite sides by the deep trench structures. The deep trench structures are spaced so as to form RESURF regions for the drift region. Trench gates are formed in trenches in the substrate over the vertical drift regions. The body regions are located in the substrate over the vertical drift regions.

A semiconductor device having a vertical drain extended MOS transistor may be formed by forming deep trench structures to define vertical drift regions of the transistor, so that each vertical drift region is bounded on at least two opposite sides by the deep trench structures. The deep trench structures are spaced so as to form RESURF regions for the drift region. Trench gates are formed in trenches in the substrate over the vertical drift regions. The body regions are located in the substrate over the vertical drift regions.

The present disclosure relates to semiconductor devices. The teachings thereof may be embodied in metal oxide semiconductor field effect transistors (MOSFET) and methods for their manufacture. Some embodiments may include: depositing a base within an epitaxial layer; implanting a source implant extending into the base, wherein the epitaxial layer, the base, and the source implant form a continuous plane surface; depositing an insulating layer on the continuous plane surface forming a gate in contact with both the epitaxial layer and the base; opening a contact groove through the insulating layer to expose a central portion of the source implant; depositing a layer of photoresist on top of the insulating layer above exposed portions of the source implant; patterning a set of stripes in the photoresist, each stripe perpendicular to the contact groove; etching the set of stripes with an etch chemistry selective to the insulating layer; and filling the contact groove with a conductive material creating a base-source contact groove reaching through the insulating layer to the surface of the source implant and comprising a plurality of sections spaced apart from each other reaching through the source implant into the base.

The present disclosure relates to semiconductor devices. The teachings thereof may be embodied in metal oxide semiconductor field effect transistors (MOSFET) and methods for their manufacture. Some embodiments may include: depositing a base within an epitaxial layer; implanting a source implant extending into the base, wherein the epitaxial layer, the base, and the source implant form a continuous plane surface; depositing an insulating layer on the continuous plane surface forming a gate in contact with both the epitaxial layer and the base; opening a contact groove through the insulating layer to expose a central portion of the source implant; depositing a layer of photoresist on top of the insulating layer above exposed portions of the source implant; patterning a set of stripes in the photoresist, each stripe perpendicular to the contact groove; etching the set of stripes with an etch chemistry selective to the insulating layer; and filling the contact groove with a conductive material creating a base-source contact groove reaching through the insulating layer to the surface of the source implant and comprising a plurality of sections spaced apart from each other reaching through the source implant into the base.

An array substrate is provided, wherein a pixel electrode has the same material as a source/drain and has a thickness less than that of the source/drain, or a common electrode has the same material as a gate and has a thickness less than that of the gate, which guarantees transmittance of the array substrate while reducing the process complexity. A display device and a manufacturing method of the array substrate are also provided.

An array substrate is provided, wherein a pixel electrode has the same material as a source/drain and has a thickness less than that of the source/drain, or a common electrode has the same material as a gate and has a thickness less than that of the gate, which guarantees transmittance of the array substrate while reducing the process complexity. A display device and a manufacturing method of the array substrate are also provided.

Various methods and devices that involve body contacted transistors are disclosed. An exemplary method comprises forming a gate on a planar surface of a semiconductor wafer. The gate covers a channel of a first conductivity type that is opposite to a second conductivity type. The method also comprises implanting a body dose of dopants on a source side of the gate using the gate to mask the body dose of dopants. The body dose of dopants spreads underneath the channel to form a deep well. The body dose of dopants has the first conductivity type. The method also comprises implanting, subsequent to implanting the body dose of dopants, a source dose of dopants on the source side of the gate to form a source. The method also comprises forming a source contact that is in contact with the deep well at the planar surface of the semiconductor wafer.

Various methods and devices that involve body contacted transistors are disclosed. An exemplary method comprises forming a gate on a planar surface of a semiconductor wafer. The gate covers a channel of a first conductivity type that is opposite to a second conductivity type. The method also comprises implanting a body dose of dopants on a source side of the gate using the gate to mask the body dose of dopants. The body dose of dopants spreads underneath the channel to form a deep well. The body dose of dopants has the first conductivity type. The method also comprises implanting, subsequent to implanting the body dose of dopants, a source dose of dopants on the source side of the gate to form a source. The method also comprises forming a source contact that is in contact with the deep well at the planar surface of the semiconductor wafer.

The present description relates to a gallium nitride transistor which includes at least one source/drain structure having low contact resistance between a 2D electron gas of the gallium nitride transistor and the source/drain structure. The low contact resistance may be a result of at least a portion of the source/drain structure being a single-crystal structure abutting the 2D electron gas. In one embodiment, the single-crystal structure is grown with a portion of a charge inducing layer of the gallium nitride transistor acting as a nucleation site.