According to another embodiment, a method of forming a transistor is provided. The method includes the following operations: providing a substrate; providing a source over the substrate; providing a channel connected to the source; providing a drain connected to the channel; providing a gate insulator adjacent to the channel; providing a gate adjacent to the gate insulator; providing a first interlayer dielectric between the source and the gate; and providing a second interlayer dielectric between the drain and the gate, wherein at least one of the formation of the source, the drain, and the channel includes about 20-95 atomic percent of Sn.

Disclosed is a method for manufacturing a semiconductor device. The method for manufacturing the semiconductor device includes forming a p-channel over a semiconductor substrate. A gate dielectric layer is formed over the p-channel. The gate dielectric layer is doped with a dopant. A first metal gate is formed over the gate dielectric layer.

A nanowire semiconductor device having a high-quality epitaxial layer. The semiconductor device may include: a substrate; one or more nanowires spaced apart from the substrate, wherein the nanowires each extend along a curved longitudinal extending direction; and one or more semiconductor layers formed around peripheries of the respective nanowires to at least partially surround the respective nanowires, wherein the respective semiconductor layers around the respective nanowires are spaced apart from each other.

A method for fabricating a semiconductor device is carried out so that silicon nanowires may be made of vertically stacked one or more floating silicon layers, and a silicon buffer layer may be surrounded on each surface of the silicon nanowires with a sufficient thickness, e.g., close to the diameter of the nanowire, and then a silicon germanium shell may be formed on it. Thus, a semiconductor device having a silicon germanium shell channel structure can be fabricated with a uniform thickness even on a bulk silicon substrate using a conventional silicon CMOS process.

Embodiments of the invention are directed to a nano sheet semiconductor device fabrication method that includes forming a gate spacer along a gate region of the nanosheet FET device. Channel nanosheet is formed such that each one has a desired final channel nanosheet width dimension (Wf). An inner spacer is formed between the channel nanosheets. Forming the gate spacer and the inner spacer includes, subsequent to forming the channel nanosheets to the desired Wf, conformally depositing a layer of the spacer material along a sidewall of the gate region, along sidewalls of the channel nanosheets, and within a space between the channel nanosheets. The gate spacer is formed from a portion of the layer of the spacer material along the sidewall of the gate region. The inner spacer is formed from a portion of the layer of the spacer material within the space between the channel nanosheets.

A semiconductor device includes a drain, a source, a gate electrode, and a nanowire between the source and drain. The nanowire has a first section with a first thickness and a second section with a second thickness greater than the first thickness. The second section is between the first section and at least one of the source or drain. The first nanowire includes a channel when a voltage is applied to the gate electrode.

A method for fabricating a semiconductor device is carried out so that silicon nanowires may be made of vertically stacked one or more floating silicon layers, and a silicon buffer layer may be surrounded on each surface of the silicon nanowires with a sufficient thickness, e.g., close to the diameter of the nanowire, and then a silicon germanium shell may be formed on it. Thus, a semiconductor device having a silicon germanium shell channel structure can be fabricated with a uniform thickness even on a bulk silicon substrate using a conventional silicon CMOS process.

A method of manufacturing a semiconductor device includes forming a first semiconductor layer having a first composition over a semiconductor substrate, and forming a second semiconductor layer having a second composition over the first semiconductor layer. Another first semiconductor layer having the first composition is formed over the second semiconductor layer. A third semiconductor layer having a third composition is formed over the another first semiconductor layer. The first semiconductor layers, second semiconductor layer, and third semiconductor layer are patterned to form a fin structure. A portion of the third semiconductor layer is removed thereby forming a nanowire comprising the second semiconductor layer, and a conductive material is formed surrounding the nanowire. The first semiconductor layers, second semiconductor layer, and third semiconductor layer include different materials.

Methods for manufacturing semiconductor structures are provided. The method for manufacturing the semiconductor structure includes forming a fin structure protruding from a substrate and forming a source/drain structure over the fin structure. The method for manufacturing a semiconductor structure further includes forming a metallic layer over the source/drain structure and forming an oxide film on a sidewall of the source/drain structure. In addition, the oxide film and the metallic layer are both in direct contact with the source/drain structure.

An apparatus including a three-dimensional semiconductor body including a channel region and junction regions disposed on opposite sides of the channel region, the three-dimensional semiconductor body including a plurality of nanowires including a germanium material disposed in respective planes separated in the junction regions by a second material, wherein a lattice constant of the second material is similar to a lattice constant of the germanium material; and a gate stack disposed on the channel region, the gate stack including a gate electrode disposed on a gate dielectric. A method of including forming a plurality of nanowires in separate planes on a substrate, each of the plurality of nanowires including a germanium material and separated from an adjacent nanowire by a sacrificial material; disposing a gate stack on the plurality of nanowires in a designated channel region, the gate stack including a dielectric material and a gate electrode.