Provided is a method of manufacturing a semiconductor device capable of suppressing variation in thickness of oxide films among a plurality of SiC wafers. Forming first inorganic films on lower surfaces of a plurality of SiC wafer, and then performing etching of the plurality of SiC wafers so that 750 nm or more of the first inorganic film is left in thickness, and then forming oxide films on upper surfaces of the plurality of SiC wafers by performing thermal oxidation treatment in a state in which a first SiC wafer of the plurality of SiC wafers is placed directly below any one of at least one wafer, including at least one of a dummy wafer and a monitor wafer, and a second SiC wafer of the plurality of SiC wafers is placed directly below a third SiC wafer of the plurality of SiC wafers.

An IC structure comprises a substrate, a first SRAM cell, and a second SRAM cell. The first SRAM cell is formed over the substrate and comprises a first N-type transistor. The second SRAM cell is formed over the substrate and comprises a second N-type transistor. A gate structure of first N-type transistor of the first SRAM cell has a different work function metal composition than a gate structure of the second N-type transistor of the second SRAM cell.

Thin film transistors having strain-inducing structures integrated with two-dimensional (2D) channel materials are described. In an example, an integrated circuit structure includes a two-dimensional (2D) material layer above a substrate. A gate stack is on the 2D material layer, the gate stack having a first side opposite a second side. A first gate spacer is on the 2D material layer and adjacent to the first side of the gate stack. A second gate spacer is on the 2D material layer and adjacent to the second side of the gate stack. The first gate spacer and the second gate spacer induce a strain on the 2D material layer. A first conductive structure is on the 2D material layer and adjacent to the first gate spacer. A second conductive structure is on the 2D material layer and adjacent to the second gate spacer.

A stacked field effect transistor device is provided. The stacked field effect transistor device includes a lower semiconductor channel segment between a first pair of source/drains, and an upper semiconductor channel segment between a second pair of source/drains. The stacked device further includes a gate dielectric layer on the upper and lower semiconductor channel segments, and a first work function material layer on the gate dielectric layer on the lower semiconductor channel segment. The stacked device further includes a first conductive gate fill on the first work function material layer, and a replacement work function material layer on the gate dielectric layer on the upper semiconductor channel segment and the first conductive gate fill, wherein the replacement work function material layer is a different work function material from the first work function material layer. The device further includes a replacement conductive gate fill on the replacement work function material layer.

Thin film transistors having semiconductor structures integrated with two-dimensional (2D) channel materials are described. In an example, an integrated circuit structure includes a two-dimensional (2D) material layer above a substrate. A gate stack is above the 2D material layer, the gate stack having a first side opposite a second side. A semiconductor structure including germanium is included, the semiconductor structure laterally adjacent to and in contact with the 2D material layer adjacent the first side of the gate stack. A first conductive structure is adjacent the first side of the second gate stack, the first conductive structure over and in direct electrical contact with the semiconductor structure. The semiconductor structure is intervening between the first conductive structure and the 2D material layer. A second conductive structure is adjacent the second side of the second gate stack, the second conductive structure over and in direct electrical contact with the 2D material layer.

A semiconductor device of embodiments includes: an element region including a transistor and a first diode; a termination region surrounding the element region and including a second diode; and an intermediate region between the element region and the termination region. The element region includes a first electrode, a second electrode, a gate electrode, a silicon carbide layer, and a gate insulating layer. The termination region includes a first wiring layer electrically connected to the first electrode, the second electrode, and the silicon carbide layer. The intermediate region includes a gate electrode pad, a first connection layer electrically connecting the first electrode and a part of the first wiring layer, a second connection layer electrically connecting the first electrode and another part of the first wiring layer, a second wiring layer electrically connected to the gate electrode pad and the gate electrode, and the silicon carbide layer.

A semiconductor device includes: a second electrode, located in a semiconductor part, extending in a first direction; a third electrode, located in the semiconductor part, including a first portion, a second portion, and a first middle portion positioned below the second electrode between the first portion and the second portion, the second electrode being located between the first portion and the second portion in the first direction; a fourth electrode, located above the semiconductor part, including a pad portion separated from the second electrode and the second portion in a second direction, and a protrusion protruding from the pad portion and covering the second electrode and being connected to the second electrode; and a fifth electrode, located above the semiconductor part, including a first covering portion being connected to the first contact portion and a second covering portion being connected to the first portion.

The embodiments herein describe a vertical field effect transistor (FET) with a gate that includes different work function metals (WFMs). Each WFM can be made up of one material (or one layer) or multiple materials forming multiple layers. In any case, the gate includes at least two different WFMs. For example, a first WFM may have a different material or layer than a second WFM in the gate, or one layer of the first WFM may have a different thickness than a corresponding layer in the second WFM. Having different WFMs in the gate can reduce the gate induced drain leakage (GIDL) in the FET.

A semiconductor device including a gate separation region is provided. The semiconductor device includes an isolation region between active regions; interlayer insulating layers on the isolation region; gate line structures overlapping the active regions, disposed on the isolation region, and having end portions facing each other; and a gate separation region disposed on the isolation region, and disposed between the end portions of the gate line structures facing each other and between the interlayer insulating layers. The gate separation region comprises a gap fill layer and a buffer structure, the buffer structure includes a buffer liner disposed between the gap fill layer and the isolation region, between the end portions of the gate line structures facing each other and side surfaces of the gap fill layer, and between the interlayer insulating layers and the side surfaces of the gap fill layer.

A power semiconductor device includes a substrate, a first well, a second well, a drain, a source, a first gate structure, a second gate structure and a doping region. The first well has a first conductivity and extends into the substrate from a substrate surface. The second well has a second conductivity and extends into the substrate from the substrate surface. The drain has the first conductivity and is disposed in the first well. The source has the first conductivity and is disposed in the second well. The first gate structure is disposed on the substrate surface and at least partially overlapping with the first well and second well. The second gate structure is disposed on the substrate surface and overlapping with the second well. The doping region has the first conductivity, is disposed in the second well and connects the first gate structure with the second gate structure.