A structure includes a substrate and a tunnel field effect transistor (TFET). The TFET includes a source region disposed in the substrate having an overlying source contact, the source region containing first semiconductor material having a first doping type; a drain region disposed in the substrate having an overlying drain contact, the drain region containing second semiconductor material having a second, opposite doping type; and a gate structure that overlies a channel region between the source and the drain. The source region and the drain region are asymmetric with respect to one another such that one contains a larger volume of semiconductor material than the other one. A method is disclosed to fabricate a plurality of the TFETs using a plurality of spaced apart mandrels having spacers. A pair of the mandrels and the associated spacers is processed to form four adjacent TFETs without requiring intervening lithographic processes.

A fin field effect transistor (FinFET), and a method of forming, is provided. The FinFET has a fin having one or more semiconductor layers epitaxially grown on a substrate. A first passivation layer is formed over the fins, and isolation regions are formed between the fins. An upper portion of the fins are reshaped and a second passivation layer is formed over the reshaped portion. Thereafter, a gate structure may be formed over the fins and source/drain regions may be formed.

A method for adjusting a threshold voltage includes depositing a strained liner on a gate structure to strain a gate dielectric. A threshold voltage of a transistor is adjusted by controlling an amount of strain in the liner to control an amount of work function (WF) modulating species that diffuse into the gate dielectric in a channel region. The liner is removed.

The present invention provides a semiconductor device, including a substrate, a first semiconductor layer, a plurality of first sub recess, a plurality of insulation structures and a first top semiconductor layer. The substrate has a first region disposed within an STI. The first semiconductor layer is disposed in the first region. The first sub recesses are disposed in the first semiconductor layer. The insulation structures are disposed on the first semiconductor layer. The first top semiconductor layer forms a plurality of fin structures, which are embedded in the first sub recesses, arranged alternatively with the insulation structures and protruding over the insulation structures.

A nitride compound semiconductor has a substrate and a nitride compound semiconductor stack on the substrate. The nitride compound semiconductor stack includes a multilayer buffer layer, a channel layer on this multilayer buffer layer, and an electron supply layer on this channel layer. A recess extends from the surface of the electron supply layer through the channel layer and the multilayer buffer layer. A heat dissipation layer in this recess is contiguous to the multilayer buffer layer and the channel layer and has a higher thermal conductivity than the multilayer buffer layer.

A method of production of a semiconducting structure including a strained portion tied to a support layer by molecular bonding, including the steps in which a cavity is produced situated under a structured part so as to strain a central portion by lateral portions, and the structured part is placed in contact and molecularly bonded with a support layer, wherein a consolidation annealing is performed, and a distal part of the lateral portions in relation to the strained portion is etched.

A semiconductor structure containing a high mobility semiconductor channel material, i.e., a III-V semiconductor material, and asymmetrical source/drain regions located on the sidewalls of the high mobility semiconductor channel material is provided. The asymmetrical source/drain regions can aid in improving performance of the resultant device. The source region contains a source-side epitaxial doped semiconductor material, while the drain region contains a drain-side epitaxial doped semiconductor material and an underlying portion of the high mobility semiconductor channel material.

Present embodiments provide for a FinFET and fabrication method thereof. The fabrication method includes two selective etching processes to form the channel. The FinFET includes a substrate, a shallow trench isolation (STI) layer, a buffer layer, a III-V group material, an oxide-isolation layer, a high-K dielectric layer and a conductor material. The STI is formed on the substrate with a trench. The buffer layer is formed on the substrate in the trench. The III-V group material is formed on the buffer layer in vertical stacked bowl shape. The oxide-isolation layer is formed between the substrate and the III-V group material. The high-K dielectric layer is formed on the STI layer and surrounding the III-V group material. The conductor material is formed surrounding the high-K dielectric layer.

A semiconductor structure includes a semiconductor substrate, at least a semiconductor layer formed on the semiconductor substrate, and at least a fin structure formed on the semiconductor layer. The semiconductor substrate includes a first semiconductor material, the semiconductor layer includes the first semiconductor material and a second semiconductor material, and the fin structure includes at least the first semiconductor material. A lattice constant of the second semiconductor material is different from a lattice constant of the first semiconductor material. The semiconductor layer includes a first width, the fin structure includes a second width, and the second width is smaller than the first width.

A method comprises providing a semiconductor alloy layer on a semiconductor substrate, forming a gate structure on the semiconductor alloy layer, forming source and drain regions in the semiconductor substrate on both sides of the gate structure, removing at least a portion of the semiconductor alloy layer overlying the source and drain regions, and forming a metal silicide region over the source and drain regions.