Gate metal is removed from a region containing transistors such as nanosheet transistors or vertical transport field-effect transistors using techniques that control the undercutting of gate metal in an adjoining region. A dielectric spacer layer is deposited on the transistors. A first etch causes the removal of gate metal over the boundary between the regions with limited undercutting of gate metal beneath the dielectric spacer layer. A subsequent etch removes the gate metal from the transistors in one region while the gate metal in the adjoining region is protected by a buffer layer. Gate dielectric material may also be removed over the boundary between regions.

A band-shaped Si pillar having a mask material layer on the top portion thereof is formed on a P+ layer. SiGe layers having mask material layers on the top portions thereof are then formed in contact with the side surfaces of the band-shaped Si pillar and the surfaces of N+ layers and the P+ layer. Si layers having mask material layers on the top portions thereof are then formed in contact with the side surfaces of the SiGe layers and the surfaces of the N+ layers. The outer peripheries of the bottom portions of the Si layers are then removed using the mask material layers as a mask to form band-shaped Si pillars. The mask material layers and the SiGe layers are then removed. Si pillars separated in the Y direction are then formed in the band-shaped Si pillars.

An embodiment semiconductor module includes a substrate, a heterogeneous thin film including a first semiconductor layer disposed on a first region of the substrate and a second semiconductor layer disposed on a second region of the substrate, a first semiconductor device disposed on the first semiconductor layer of the heterogeneous thin film, and a second semiconductor device disposed on the second semiconductor layer of the heterogeneous thin film, wherein one of the first semiconductor layer or the second semiconductor layer comprises gallium oxide (Ga.sub.2O.sub.3) and the other includes silicon (Si).

Structures including a compound-semiconductor-based device and a silicon-based device integrated on a semiconductor substrate and methods of forming such structures. The structure includes a first semiconductor layer having a top surface and a faceted surface that fully surrounds the top surface. The top surface has a first surface normal, and the faceted surface has a second surface normal that is inclined relative to the first surface normal. A layer stack that includes second semiconductor layers is positioned on the faceted surface of the first semiconductor layer. Each of the second semiconductor layers contains a compound semiconductor material. A silicon-based device is located on the top surface of the first semiconductor layer, and a compound-semiconductor-based device is located on the layer stack.

A structure including a three-dimensionally stretchable single crystalline semiconductor membrane located on a substrate is provided. The structure is formed by providing a three-dimensional (3D) wavy silicon germanium alloy layer on a silicon handler substrate. A single crystalline semiconductor material membrane is then formed on a physically exposed surface of the 3D wavy silicon germanium alloy layer. A substrate is then formed on a physically exposed surface of the single crystalline semiconductor material membrane. The 3D wavy silicon germanium alloy layer and the silicon handler substrate are thereafter removed providing the structure.

A semiconductor device includes an extremely thin semiconductor-on-insulator substrate (ETSOI) having a base substrate, a thin semiconductor layer and a buried dielectric therebetween. A device channel is formed in the thin semiconductor layer. Source and drain regions are formed at opposing positions relative to the device channel. The source and drain regions include an n-type material deposited on the buried dielectric within a thickness of the thin semiconductor layer. A gate structure is formed over the device channel.

The present disclosure falls into the field of optoelectronics, particularly, includes the design, epitaxial growth, fabrication, and characterization of Laser Diodes (LDs) operating in the ultraviolet (UV) to infrared (IR) spectral regime on patterned substrates (PSs) made with (formed on) low cost, large size Si, or GaN on sapphire, GaN, and other wafers. We disclose three types of PSs, which can be universal substrates, allowing any materials (III-Vs, II-VIs, etc.) grown on top of it with low defect and/or dislocation density.

The present disclosure relates to a part including silicon carbide layer and manufacturing method thereof, and the manufacturing method according to the present disclosure includes preparing a graphite substrate, and laminating a silicon carbide layer on a surface of the graphite substrate, wherein at the laminating the silicon carbide layer, the silicon carbide layer is laminated such that the thickness of the silicon carbide layer is 0.01 to 1 times the thickness of the graphite substrate, thereby improving the durability of the part including silicon carbide layer.

A method for making a semiconductor device may include forming an inverted T channel on a substrate, with the inverted T channel comprising a superlattice. The superlattice may include a plurality of stacked groups of layers, with each group of layers comprising a plurality of stacked base semiconductor monolayers defining a base semiconductor portion, and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions. The method may further include forming source and drain regions on opposing ends of the inverted T channel, and forming a gate overlying the inverted T channel between the source and drain.

Exemplary deposition methods may include delivering a silicon-containing precursor and an inert gas to a processing region of a semiconductor processing chamber. The methods may include providing a hydrogen-containing precursor with the silicon-containing precursor and the inert gas. The methods may include forming a plasma of all precursors within the processing region of a semiconductor processing chamber. The methods may include depositing a silicon-containing material on a substrate disposed within the processing region of the semiconductor processing chamber. The processing region may be maintained free of helium delivery during the deposition method.