There is provided a method of manufacturing a semiconductor device. The method of manufacturing comprises a film formation process of forming a molybdenum layer that is mainly made of molybdenum (Mo), on at least one of a semiconductor layer, an insulating film and an electrode in the semiconductor device; a heat treatment process of heating the molybdenum layer at temperature of not lower than 200 C.; and a dry etching process of processing the semiconductor device that includes the formed molybdenum layer by dry etching, subsequent to the heat treatment process.

A method for forming a semiconductor device, including forming one or more fin structures on a semiconductor substrate, where the fin structure defines source and drain regions. The method includes forming a gate stack, depositing a first contact insulator layer, and applying an etching process to portions of the first insulator layer to form a trench that extends to the source region. The method also includes depositing an epitaxial lower band gap source material into the trench and extending to the source region, depositing a second insulator layer, applying a second etching process to portions of the second insulator layer to form a trench that extends to the source and drain regions, and depositing a metalizing material over the substrate.

Embodiments of the invention provide methods for forming III-V gate-all-around field effect transistors on silicon substrates that utilize Aspect-Ratio Trapping to reduce or eliminate dislocation defects associated with lattice mismatches. A field dielectric material defining a trench is formed on a crystalline silicon substrate. A channel feature comprising III-V material is subsequently formed inside the trench. Source/drain features are then formed at both ends of the channel feature inside the trench. Lastly, gate dielectric layers and a gate feature are formed surrounding a portion of the channel feature.

Embodiments described herein generally relate to methods and structures for forming precise fins comprising Group III-V elements on a silicon substrate. A buffer layer is deposited in a trench formed in the dielectric material on a substrate. An isolation layer is then deposited over the buffer layer. A portion of the isolation layer is removed allowing for a precisely sized Group III-V channel layer to be deposited on the isolation layer.

A semiconductor device includes a first channel region disposed over a substrate, a first source region and a first drain region disposed over the substrate and connected to the first channel region such that the first channel region is disposed between the first source region and the first drain region, a gate dielectric layer disposed on and wrapping the first channel region, a gate electrode layer disposed on the gate dielectric layer and wrapping the first channel region, and a second source region and a second drain region disposed over the substrate and below the first source region and the first drain region, respectively. The second source region and the second drain region are in contact with the gate dielectric layer. A lattice constant of the first source region and the first drain region is different from a lattice constant of the second source region and the second drain region.

A material layer, a semiconductor device including the material layer, and methods of forming the material layer and the semiconductor device are provided herein. A method of forming a SiOCN material layer may include supplying a silicon source onto a substrate, supplying a carbon source onto the substrate, supplying an oxygen source onto the substrate, supplying a nitrogen source onto the substrate, and supplying hydrogen onto the substrate. When a material layer is formed according to a method of the present inventive concepts, a material layer having a high tolerance to wet etching and/or good electric characteristics may be formed, and may even be formed when the method is performed at a low temperature.

The present disclosure provides a TFT array substrate and manufacturing method thereof, forming a class structure of graphene-like two-dimensional layered semiconductor material on a base substrate and transferring the class structure of graphene-like two-dimensional layered semiconductor material on the designated position of the soft substrate to be a semiconductor active layer of the array substrate, therefore the semiconductor active layer of the TFT array substrate of the present disclosure uses a class structure of graphene-like two-dimensional layered semiconductor material to makes the array substrate having the advantage of higher electron mobility and mechanical property, excellent flexural resistance and reducing thickness of the substrate greatly.

A GaN-based enhancement-mode power electronic device and a method for manufacturing the same. The GaN-based enhancement-mode power electronic device comprises: a substrate; a thin barrier Al(In,Ga)N/GaN heterostructure formed on the substrate; a gate, a source, and a drain formed on the thin barrier Al(In,Ga)N/GaN heterostructure. An AlN or SiNx passivation layer is formed on access regions between the gate and the source and between the gate and the drain, respectively, such that two dimensional electron gas is recovered in channels of the thin barrier Al(In,Ga)N/GaN heterostructure below the MN passivation layer by utilizing the MN passivation layer having polarization characteristics, or by using the SiNx passivation layer with positive fixed bulk/interface charges, so as to reduce on-resistance of the device and inhibit high-voltage current collapse in the device.

A structure and method for fabricating a vertical heterojunction tunnel field effect transistor (TFET) using limited lithography steps is disclosed. The fabrication of a second conductivity type source/drain region may utilize a single lithography step to form a first-type source/drain region, and a metal contact thereon, adjacent to a gate stack having a first conductivity type source/drain region on an opposite side.

Devices, and methods of forming such devices, having a material that is semimetal when in bulk but is a semiconductor in the devices are described. An example structure includes a substrate, a first source/drain contact region, a channel structure, a gate dielectric, a gate electrode, and a second source/drain contact region. The substrate has an upper surface. The channel structure is connected to and over the first source/drain contact region, and the channel structure is over the upper surface of the substrate. The channel structure has a sidewall that extends above the first source/drain contact region. The channel structure comprises a bismuth-containing semiconductor material. The gate dielectric is along the sidewall of the channel structure. The gate electrode is along the gate dielectric. The second source/drain contact region is connected to and over the channel structure.