A dual gate CMOS structure including a semiconductor substrate; a first channel structure including a first semiconductor material and a second channel structure including a second semiconductor material on the substrate. The first semiconductor material including Si.sub.xGe.sub.1-x where x=0 to 1 and the second semiconductor material including a group III-V compound material. A first gate stack on the first channel structure includes: a first native oxide layer as an interface control layer, the first native oxide layer comprising an oxide of the first semiconductor material; a first high-k dielectric layer; a first metal gate layer. A second gate stack on the second channel structure includes a second high-k dielectric layer; a second metal gate layer. The interface between the second channel structure and the second high-k dielectric layer is free of any native oxides of the second semiconductor material.

An insulating layer is conformally deposited on a plurality of mesa structures in a trench on a substrate. The insulating layer fills a space outside the mesa structures. A nucleation layer is deposited on the mesa structures. A III-V material layer is deposited on the nucleation layer. The III-V material layer is laterally grown over the insulating layer.

A method of forming a semiconductor structure is provided. The method includes providing a substrate comprising, from bottom to top, a handle substrate, an insulator layer and a germanium-containing layer. Next, hard mask material portions having an opening that exposes a portion of the germanium-containing layer are formed on the substrate. An etch is then performed through the opening to provide an undercut region in the germanium-containing layer. A III-V compound semiconductor material is grown within the undercut region by utilizing an aspect ratio trapping growth process. Next, portions of the III-V compound semiconductor material are removed to provide III-V compound semiconductor material portions located between remaining portions of the germanium-containing layer.

An electrical device that includes at least one n-type field effect transistor including a channel region in a type III-V semiconductor device, and at least one p-type field effect transistor including a channel region in a germanium containing semiconductor material. Each of the n-type and p-type semiconductor devices may include gate structures composed of material layers including work function adjusting materials selections, such as metal and doped dielectric layers. The field effect transistors may be composed of fin type field effect transistors. The field effect transistors may be formed using gate first processing or gate last processing.

A radio frequency (RF) integrated circuit includes a first layer of semiconductor material in which a high electron mobility transfer (HEMT) device is formed. A semiconductor heat spreader substrate supports the first layer of semiconductor material. A pair of matching circuits are electrically connected to the HEMT device, wherein the pair of matching circuits are supported on a semiconductor substrate of a semiconductor material different than the semiconductor material of the first semiconductor heat spreader substrate. The first layer of semiconductor material and the first semiconductor heat spreader substrate have a thickness that is less than a second thickness of the semiconductor substrate supporting the pair of matching circuits.

Provided is a transistor containing a semiconductor with low density of defect states, a transistor having a small subthreshold swing value, a transistor having a small short-channel effect, a transistor having normally-off electrical characteristics, a transistor having a low leakage current in an off state, a transistor having excellent electrical characteristics, a transistor having high reliability, or a transistor having excellent frequency characteristics. An insulator is formed, a layer is formed over the insulator, oxygen is added to the insulator through the layer, the layer is removed, an oxide semiconductor is formed over the insulator to which the oxygen is added, and a semiconductor element is formed using the oxide semiconductor.

The present invention provides a method of manufacturing nanowire semiconductor device. In the active region of the PMOS the first nanowire is formed with high hole mobility and in the active region of the NMOS the second nanowire is formed with high electron mobility to achieve the objective of improving the performance of nanowire semiconductor device.

A method for forming a semiconductor structure includes sequentially providing a semiconductor substrate having NFET regions and NFET regions:, forming an insulation layer on the semiconductor substrate; forming a sacrificial layer on the insulation layer; forming first trenches in the PFET regions, and second trenches in the NFET regions; forming a third trench on the bottom of each of the first trenches and the second trenches; forming a first buffer layer in each of the first trenches and the second trenches by filling; the third trenches; forming a first semiconductor layer on each of the first buffer layers in the first trenches and the second teaches; removing the first semiconductor layers in the second trenches; forming a second buffer layer with a top surface lower than the insolation layer in each of second trenches; and forming a second semiconductor layer on each of the second buffer layers.

Provided herein is a multi-channel finFET having a plurality of fins prepared by a process. The process includes forming a series of mandrels on hard mask layer which overlays a semiconductor layer. The semiconductor layer has areas of a first semiconductor material and a second semiconductor material in contact with the hard mask layer. The process includes applying a first conformal coating on the hard mask layer and the series of mandrels, to form spacer layer sacrificial fins. The process includes removing the first conformal coating from horizontal surfaces while retaining the first conformal coating on sidewalls of the series of mandrels. The process includes removing the series of mandrels and etching into a material of the hard mask layer using the spacer layer sacrificial fins as a mask.

A bootstrap circuit of which the capacitance of a bootstrap capacitor is small and which requires a shorter precharge period is provided. The bootstrap circuit includes transistors M41 and M42, capacitors BSC1 and BSC2, an inverter INV41, and keeper circuits 43 and 44. A signal OSG with a high voltage is generated from an input signal OSG_IN. As the signal OSG_IN is made a high level, a node SWG is made a high level by BSC1. After a signal BSE1 is made a high level and the node SWG is made a low level by the keeper circuit 44, a signal BSE2 is made a high level. By the capacitance coupling of BSC2, a voltage of an output terminal 22 increases.