Circuits, systems, devices, and methods related to a switch with an integrated Schottky barrier contact are discussed herein. For example, a radio-frequency switch can include an input node, an output node, and a transistor connected between the input node and the output node. The transistor can be configured to control passage of a radio-frequency signal from the input node to the output node. The transistor can include a first Schottky diode integrated into a drain of the transistor and/or a second Schottky diode integrated into a source of the transistor. The first Schottky diode and/or the second Schottky diode can be configured to compensate a non-linearity effect of the radio-frequency switch.

A semiconductor device includes: a stack structure including gate patterns and insulating patterns; a channel layer penetrating the stack structure; a memory layer penetrating the stack structure, the memory layer surrounding the channel layer; and a select transistor connected to the channel layer. The select transistor includes: a carbon layer Schottky-joined with the channel layer; a select gate spaced apart from the carbon layer; and a gate insulating layer between the select gate and the carbon layer.

A semiconductor device is provided. The semiconductor device includes a metal layer, a semiconductor layer in electrical contact with the metal layer, a two-dimensional (2D) material layer disposed between the metal layer and the semiconductor layer and having a 2D crystal structure, and a metal compound layer disposed between the 2D material layer and the semiconductor layer.

An HEMT includes a gallium nitride layer. An aluminum gallium nitride layer is disposed on the gallium nitride layer. A gate is disposed on the aluminum gallium nitride layer. The gate includes a P-type gallium nitride and a schottky contact layer. The P-type gallium nitride contacts the schottky contact layer, and a top surface of the P-type gallium nitride entirely overlaps a bottom surface of the schottky contact layer. A protective layer covers the aluminum gallium nitride layer and the gate. A source electrode is disposed at one side of the gate, penetrates the protective layer and contacts the aluminum gallium nitride layer. A drain electrode is disposed at another side of the gate, penetrates the protective layer and contacts the aluminum gallium nitride layer. A gate electrode is disposed directly on the gate, penetrates the protective layer and contacts the schottky contact layer.

A semiconductor device includes: a stack structure including gate patterns and insulating patterns; a channel layer penetrating the stack structure; a memory layer penetrating the stack structure, the memory layer surrounding the channel layer; and a select transistor connected to the channel layer. The select transistor includes: a carbon layer Schottky-joined with the channel layer; a select gate spaced apart from the carbon layer; and a gate insulating layer between the select gate and the carbon layer.

A 3D NAND flash memory device includes a substrate, a source line on the substrate, a stacked structure on the source line, a bit line on the stacked structure, and a columnar channel portion. The stacked structure includes a first select transistor, memory cells, and a second select transistor, wherein the first select transistor includes a first select gate, the memory cells include control gates, and the second select transistor includes a second select gate. The columnar channel portion is extended axially from the source line and penetrates the stacked structure to be coupled to the bit line. The first select transistor includes a modified Schottky barrier (MSB) transistor to generate direct tunneling of majority carriers to the columnar channel portion to perform a program operation or an erase operation.

A wide gap semiconductor device has: a first MOSFET region (M0) having a first gate electrode 10 and a first source region 30 provided in a first well region 20 made of a second conductivity type; a second MOSFET region (M1) provided below a gate pad 100 and having a second gate electrode 110 and a second source region 130 provided in a second well region 120 made of the second conductivity type; and a built-in diode region electrically connected to the second gate electrode 110. The second source region 130 of the second MOSFET region (M1) is electrically connected to the gate pad 100.

There is provided a method of manufacturing a transistor, the method comprising: (a) providing a substrate having a semiconductor surface; (b) providing a graphene layer structure on a first portion of the semiconductor surface, wherein the graphene layer structure has a thickness of n graphene monolayers, wherein n is at least 2; (c) etching a first portion of the graphene layer structure to reduce the thickness of the graphene layer structure in said first portion to from n−1 to 1 graphene monolayers; (d) forming a layer of dielectric material on the first portion of the graphene layer structure; and (e) providing: a source contact on a second portion of the graphene layer structure; a gate contact on the layer of dielectric material; and a drain contact on a second portion of the semiconductor surface of the substrate.

The present invention provides a method of manufacturing a graphene transistor 101, the method comprising: (a) providing a substrate having a substantially flat surface, wherein the surface comprises an insulating region 110 and an adjacent semiconducting region 105; (b) forming a graphene layer structure 115 on the surface, wherein the graphene layer structure is disposed on and across a portion of both the insulating region and the adjacent semiconducting region; (c) forming a layer of dielectric material 120 on a portion of the graphene layer structure which is itself disposed on the semiconducting region 105; and (d) providing: a source contact 125 on a portion of the graphene layer structure which is itself disposed on the insulating region 110; a gate contact 130 on the layer of dielectric material 120 and above a portion of the graphene layer structure which is itself disposed on the semiconducting region 105; and a drain contact 135 on the semiconducting region 105 of the substrate surface.

Contact structures for semiconductor devices are disclosed. Contact structures that include a metal layer and a substrate of a semiconductor device may be annealed to provide suitable contact resistance. Localized annealed regions may be formed in a pattern within the contact structure to provide a desired contact resistance while reducing exposure of other portions of the semiconductor device to anneal conditions. The annealed regions may be formed in patterns that reduce intersections between annealed regions and fracture planes of the substrate, thereby improving mechanical robustness of the semiconductor device. The patterns may include annealed regions formed in lines that are nonparallel with fracture planes of the substrate. The patterns may also include annealed regions formed in lines that are nonparallel with peripheral edges of the substrate.