A III-N semiconductor channel is formed on a III-N transition layer formed on a (111) or (110) surface of a silicon template structure, such as a fin sidewall. In embodiments, the silicon fin has a width comparable to the III-N epitaxial film thicknesses for a more compliant seeding layer, permitting lower defect density and/or reduced epitaxial film thickness. In embodiments, a transition layer is GaN and the semiconductor channel comprises Indium (In) to increase a conduction band offset from the silicon fin. In other embodiments, the fin is sacrificial and either removed or oxidized, or otherwise converted into a dielectric structure during transistor fabrication. In certain embodiments employing a sacrificial fin, the III-N transition layer and semiconductor channel is substantially pure GaN, permitting a breakdown voltage higher than would be sustainable in the presence of the silicon fin.

Methods of forming semiconductor devices include epitaxially growing a III-V base layer over a first substrate in a first deposition chamber. The III-V base layer is transferred from the first substrate to a second substrate, and at least one III-V device layer is epitaxially grown on the III-V base layer in a second deposition chamber separate from the first deposition chamber while the III-V base layer is disposed on the second substrate. The first substrate exhibits an average coefficient of thermal expansion (CTE) closer to an average CTE exhibited by the III-V base layer than an average CTE exhibited by the second substrate. Semiconductor devices may be fabricated using such methods.

The device disclosed herein includes, among other things, a substrate made of a first semiconductor material, at least one layer of insulating material positioned above the substrate, a fin structure positioned above the layer of insulating material and the substrate, the fin structure including first, second and third layers of semiconductor material, wherein the semiconductor materials of the first, second and third layers are different than the first semiconductor material, and a gate structure around a portion of the fin structure includes the first, second and third layers of semiconductor material.

Techniques are disclosed for providing a low resistance self-aligned contacts to devices formed in a semiconductor heterostructure. The techniques can be used, for example, for forming contacts to the gate, source and drain regions of a quantum well transistor fabricated in III-V and SiGe/Ge material systems. Unlike conventional contact process flows which result in a relatively large space between the source/drain contacts to gate, the resulting source and drain contacts provided by the techniques described herein are self-aligned, in that each contact is aligned to the gate electrode and isolated therefrom via spacer material.

III-nitride materials are generally described herein, including material structures comprising III-nitride material regions and silicon-containing substrates. Certain embodiments are related to gallium nitride materials and material structures comprising gallium nitride material regions and silicon-containing substrates.

In one aspect thereof the invention provides a structure that includes a substrate having a surface and a plurality of fins supported by the surface of the substrate. The plurality of fins are formed of Group IVA-based crystalline semiconductor material and are spaced apart and generally parallel to one another. In the structure at least some of the plurality of fins comprise an amorphous region forming a nanowire precursor structure that is located along a length of the fin where a Group III-V transistor is to be located. A method to fabricate the structure and other structures is also disclosed.

A semiconductor device includes a fin having a first semiconductor material. The fin includes a source/drain (S/D) region and a channel region. The S/D region provides a top surface and two sidewall surfaces. A width of the S/D region is smaller than a width of the channel region. The semiconductor device further includes a semiconductor film over the S/D region and having a doped second semiconductor material that is different from the first semiconductor material. The semiconductor film provides a top surface and two sidewall surfaces over the top and two sidewall surfaces of the S/D region respectively. The semiconductor device further includes a metal contact over the top and two sidewall surfaces of the semiconductor film and operable to electrically communicate with the S/D region.

A transistor device includes a channel, a first source/drain region positioned on a first side of the channel, a second source/drain region positioned on a second side of the channel opposite the first side of the channel, and a tunnel barrier disposed between the channel and the first source/drain region, the tunnel barrier adapted to suppress band-to-band tunneling while the transistor device is in an off state.

A high frequency semiconductor device includes a stacked body, a gate electrode, a source electrode and a drain electrode. The gate electrode includes a bending gate part and a straight gate part. The bending gate part is extended in a zigzag shape and has first and second outer edges. The source electrode includes a bending source part and a straight source part. The bending source part has an outer edge spaced by a first distance from the first outer edge of the bending gate part along a normal direction. The drain electrode includes a bending drain part and a straight drain part. The bending drain part has an outer edge spaced by a second distance from the second outer edge of the bending gate part along the normal direction.

A high electron mobility transistor (HEMT) device with a highly resistive layer co-doped with carbon (C) and a donor-type impurity and a method for making the HEMT device is disclosed. In one embodiment, the HEMT device includes a substrate, the highly resistive layer co-doped with C and the donor-type impurity formed above the substrate, a channel layer formed above the highly resistive layer, and a barrier layer formed above the channel layer. In one embodiment, the highly resistive layer comprises gallium nitride (GaN). In one embodiment, the donor-type impurity is silicon (Si). In another embodiment, the donor-type impurity is oxygen (O).