A method for forming nanowires includes forming a plurality of epitaxial layers on a substrate, the layers including alternating material layers with high and low Ge concentration and patterning the plurality of layers to form fins. The fins are etched to form recesses in low Ge concentration layers to form pillars between high Ge concentration layers. The pillars are converted to dielectric pillars. A conformal material is formed in the recesses and on the dielectric pillars. The high Ge concentration layers are condensed to form hexagonal Ge wires with (111) facets. The (111) facets are exposed to form nanowires.

Method of making a transistor with semiconducting nanowires, including: making a semiconducting nanowire on a support, one portion of the nanowire being covered by a dummy gate, in which the dummy gate and the nanowire are surrounded by a dielectric layer, removing the dummy gate, forming a first space surrounded by first parts of the dielectric layer, making an ion implantation in a second part of the dielectric layer under said first portion, said first parts protecting third parts of the dielectric layer, etching said second part, forming a second space, making a gate in the spaces, and a dielectric portion on the gate and said first parts, making an ion implantation in fourth parts of the dielectric layer surrounding second portions of the nanowire, the dielectric portion protecting said first and third parts, etch said fourth parts.

A semiconductor device and method of formation are provided. The semiconductor device includes a substrate, a first active area over the substrate, a second active area over the substrate, a graphene channel between the first active area and the second active area, and a first in-plane gate. In some embodiments, the graphene channel, the first in-plane gate, the first active area, and the second active area include graphene. A method of forming the first in-plane gate, the first active area, the second active area, and the graphene channel from a single layer of graphene is also provided.

A method for forming a semiconductor structure includes forming a strained silicon germanium layer on top of a substrate. At least one patterned hard mask layer is formed on and in contact with at least a first portion of the strained silicon germanium layer. At least a first exposed portion and a second exposed portion of the strained silicon germanium layer are oxidized. The oxidizing process forms a first oxide region and a second oxide region within the first and second exposed portions, respectively, of the strained silicon germanium.

The present invention provides a field effect transistor and the method for preparing such a filed effect transistor. The filed effect transistor comprises a semiconductor, germanium nanowires, a first III-V compound layer surrounding the germanium nanowires, a semiconductor barrier layer, a gate dielectric layer and a gate electrode sequentially formed surrounding the first III-V compound layer, and source/drain electrodes are respectively located at each side of the gate electrode and on the first III-V compound layer. According to the present invention, the band width of the barrier layer is greater than that of the first III-V compound layer, and the band curvatures of the barrier layer and the first III-V compound layer are different, therefore, a two-dimensional electron gas (2DEG) is formed in the first III-V compound layer near the barrier layer boundary. Since the 2DEG has higher mobility, the performance of the filed effect transistor improved. Besides, the performance of the filed effect transistor also improved due to the structure is a gate-all-around structure.

A semiconductor device may include a strain relaxed buffer layer provided on a substrate to contain silicon germanium, a semiconductor pattern provided on the strain relaxed buffer layer to include a source region, a drain region, and a channel region connecting the source region with the drain region, and a gate electrode enclosing the channel region and extending between the substrate and the channel region. The source and drain regions may contain germanium at a concentration of 30 at % or higher.

Provided are electronic devices and methods of manufacturing same. An electronic device includes an energy barrier forming layer on a substrate, an upper channel material layer on the substrate, and a gate electrode that covers the upper channel material layer and the energy barrier forming layer. The gate electrode includes a side gate electrode portion that faces a side surface of the energy barrier forming layer. The side gate electrode may be configured to cause an electric field to be applied directly on the energy barrier forming layer via the side surface of the energy barrier forming layer, thereby enabling adjustment of the energy barrier between the energy barrier forming layer and the upper channel material layer. The electronic device may further include a lower channel material layer that is provided on the substrate and does not contact the upper channel material layer.

A method of making a nanowire device includes disposing a first nanowire stack over a substrate, the first nanowire stack including alternating layers of a first and second semiconducting material, the first semiconducting material contacting the substrate and the second semiconducting material being an exposed surface; disposing a second nanowire stack over the substrate, the second nanowire stack including alternating layers of the first and second semiconducting materials, the first semiconducting material contacting the substrate and the second semiconducting material being an exposed surface; forming a first gate spacer along a sidewall of a first gate region on the first nanowire stack and a second gate spacer along a sidewall of a second gate region on the second nanowire stack; oxidizing a portion of the first nanowire stack within the first gate spacer; and removing the first semiconducting material from the first nanowire stack and the second nanowire stack.

A Schottky barrier device is provided herein that includes a TMD layer on a substrate, a graphene layer on the TMD layer, an electrolyte layer on the TMD layer, and a source gate contact on the electrolyte layer. A drain contact can be provided on the TMD layer and a source contact can be provided on the graphene layer. As ionic gating from the source gate contact and electrolyte layer is used to adjust the Schottky barrier height this Schottky barrier device can be referred to as an ionic control barrier transistor or ionic barristor.

A semiconductor device including a gate structure present on at least two suspended channel structures, and a composite spacer present on sidewalls of the gate structure. The composite spacer may include a cladding spacer present along a cap portion of the gate structure, and an inner spacer along the channel portion of the gate structure between adjacent channel semiconductor layers of the suspended channel structures. The inner spacer may include a crescent shape with a substantially central seam.