A semiconductor device and method of making the same wherein the semiconductor device includes a pFET region including a SiGe channel having a Si-rich top surface within the gate portion, and an nFET region including a Si channel. The method includes subjecting both the pFET and nFET regions to a single high-temperature anneal process thereby avoiding the need for an additional spike anneal process at RMG module.

A semiconductor device includes a semiconductive channel region, a semiconductive protection layer, a gate structure, and a pair of gate spacers. The semiconductive protection layer is on and in contact with the channel. The gate structure is above the semiconductive protection layer and includes gate dielectric layer and a gate electrode. The gate dielectric layer is above the semiconductive protection layer. The gate electrode is above the gate dielectric layer. The gate spacers are on opposite sides of the gate structure. The semiconductive protection layer extends from an inner sidewall of a first one of the pair of gate spacers to an inner sidewall of a second one of the pair of gate spacers.

Disclosed is an ion controllable transistor-based neuromorphic synaptic device used for a memory and a neuromorphic computing in such a manner that a synaptic weight is analogically updated and maintained. The ion controllable transistor-based neuromorphic synaptic device includes a channel area formed on a semiconductor substrate; a source area and a drain area formed at both sides of the channel area, respectively; an interlayer insulating film provided on the channel area; a gate area formed on the interlayer insulating film; and a solid electrolyte layer inserted between the interlayer insulating film and the gate area.

A method for fabricating a semiconductor device includes forming a deposition-type interface layer over a substrate, converting the deposition-type interface layer into an oxidation-type interface layer, forming a high-k layer over the oxidation-type interface layer, forming a dipole interface on an interface between the high-k layer and the oxidation-type interface layer, forming a conductive layer over the high-k layer, and patterning the conductive layer, the high-k layer, the dipole interface, and the oxidation-type interface layer to form a gate stack over the substrate.

A transistor includes a silicon germanium layer, a gate stack, and source and drain features. The silicon germanium layer has a channel region. The silicon germanium layer has a first silicon-to-germanium ratio. The gate stack is disposed over the channel region of the silicon germanium layer and includes a silicon germanium oxide layer over and in contact with the channel region of the silicon germanium layer, a high-κ dielectric layer over the silicon germanium oxide layer, and a gate electrode over the high-κ dielectric layer. The silicon germanium oxide layer has a second silicon-to-germanium ratio, and the second silicon-to-germanium ratio is substantially the same as the first silicon-to-germanium ratio.

A semiconductor structure includes: a germanium layer; and a first insulating film that is formed on an upper surface of the germanium layer, primarily contains germanium oxide and a substance having an oxygen potential lower than an oxygen potential of germanium oxide, and has a physical film thickness of 3 nm or less; wherein a half width of frequency to height in a 1 μm square area of the upper surface of the germanium layer is 0.7 nm or less.

Tunneling field-effect transistors including silicon, germanium or silicon germanium channels and III-N source regions are provided for low power operations. A broken-band heterojunction is formed by the source and channel regions of the transistors. Fabrication methods include selective anisotropic wet-etching of a silicon substrate followed by epitaxial deposition of III-N material and/or germanium implantation of the substrate followed by the epitaxial deposition of the III-N material.

A method for in-situ dry cleaning of a SiGe semiconductor surface doses the SiGe surface with ex-situ wet HF in a clean ambient environment or in-situ dosing with gaseous NH.sub.4F to remove oxygen containing contaminants. Dosing the SiGe surface with atomic H removes carbon containing contaminants. Low temperature annealing pulls the surface flat. Passivating the SiGe semiconductor surface with H.sub.2O.sub.2 vapor for a sufficient time and concentration forms an a oxygen monolayer(s) of —OH sites on the SiGe. Second annealing the SiGe semiconductor surface is conducted at a temperature below that which would induce dopant diffusion. A method for in-situ dry cleaning of a SiGe semiconductor surface, ex-situ degreases the Ge containing semiconductor surface and removes organic contaminants. The surface is then dosed with HF(aq) or NH4F(g) generated via NH.sub.3+NH or NF.sub.3 with H.sub.2 or H.sub.2O to remove oxygen containing contaminants. In-situ dosing of the SiGe surface with atomic H removes carbon containing contaminants.

Semiconductor devices and methods of manufacture thereof are disclosed. In some embodiments, a method of manufacturing a semiconductor device includes providing a substrate, the substrate includes a first fin, a second fin, and an isolation region disposed between the first fin and the second fin. The second fin includes a different material than a material of the substrate. The method includes forming an oxide over the first fin, the second fin, and a top surface of the isolation region at a temperature of about 400 degrees C. or less, and post-treating the oxide at a temperature of about 600 degrees C. or less.

A semiconductor device and a method for fabricating a semiconductor device involve a semiconductor layer that includes a first material and a second material. The first and second materials can be silicon and germanium. A contact of the device has a portion proximal to the semiconductor layer and a portion distal to the semiconductor layer. The distal portion includes the first material and the second material. A metal layer formed adjacent to the relaxed semiconductor layer and adjacent to the distal portion of the contact is simultaneously reacted with the relaxed semiconductor layer and with the distal portion of the contact to provide metallic contact material.