A semiconductor device includes a graphene film disposed on a substrate and formed of atomic layers of graphene that are stacked, a source electrode and a drain electrode disposed on the graphene film, and a gate electrode disposed on the graphene film between the source electrode and the drain electrode with a gate insulator film interposed between the gate electrode and the graphene film, wherein a first number of the atomic layers of the graphene film in a source region where the source electrode is located and a drain region where the drain electrode is located is greater than a second number of the atomic layers of the graphene film in a channel region where the gate electrode is located.

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 for producing a layer of strained semiconductor material, the method comprising steps for: a) formation on a substrate of a stack comprising a first semiconductor layer based on a first semiconductor material coated with a second semiconductor layer based on a second semiconductor material having a different lattice parameter to that of the first semiconductor material, b) producing on the second semiconductor layer a mask having a symmetry, c) rendering amorphous the first semiconductor layer along with zones of the second semiconductor layer without rendering amorphous one or a plurality of regions of the second semiconductor layer protected by the mask and arranged respectively opposite the masking block(s), d) performing recrystallization of the regions rendered amorphous and the first semiconductor layer resulting in this first semiconductor layer being strained (FIG. 1A).

Common-substrate semiconductor devices having nanowires or semiconductor bodies with differing material orientation or composition and methods to form such common-substrate devices are described. For example, a semiconductor structure includes a first semiconductor device having a first nanowire or semiconductor body disposed above a crystalline substrate. The first nanowire or semiconductor body is composed of a semiconductor material having a first global crystal orientation. The semiconductor structure also includes a second semiconductor device having a second nanowire or semiconductor body disposed above the crystalline substrate. The second nanowire or semiconductor body is composed of a semiconductor material having a second global crystal orientation different from the first global orientation. The second nanowire or semiconductor body is isolated from the crystalline substrate by an isolation pedestal disposed between the second nanowire or semiconductor body and the crystalline substrate.

Transistor structures having channel regions comprising alternating layers of compressively and tensilely strained epitaxial materials are provided. The alternating epitaxial layers can form channel regions in single and multigate transistor structures. In alternate embodiments, one of the two alternating layers is selectively etched away to form nanoribbons or nanowires of the remaining material. The resulting strained nanoribbons or nanowires form the channel regions of transistor structures. Also provided are computing devices comprising transistors comprising channel regions comprised of alternating compressively and tensilely strained epitaxial layers and computing devices comprising transistors comprising channel regions comprised of strained nanoribbons or nanowires.

The benefits of strained semiconductors are combined with silicon-on-insulator approaches to substrate and device fabrication. A structure includes a relaxed substrate including a bulk material, a strained layer directly on the relaxed substrate, where a strain of the strained layer is not induced by the relaxed substrate, and a transistor formed on the strained layer.

A semiconductor is provided that includes an nFET gate structure straddling over a first nanowire stack and a portion of a first SiGe layer having a first Ge content. The first nanowire stack comprises alternating layers of a tensily strained silicon layer, and a second SiGe layer having a second Ge content that is greater than the first Ge content and being compressively strained. Portions of the tensily strained silicon layers extend beyond sidewalls surfaces of the nFET gate structure and are suspended. The structure further includes a pFET gate structure straddling over a second nanowire stack and another portion of the first SiGe layer. The second nanowire stack comprises alternating layers of the tensily strained silicon layer, and the second SiGe layer. Portions of the second SiGe layers extend beyond sidewalls surfaces of the pFET gate structure and are suspended.

A method for forming a semiconductor device is provided. The method comprises forming a device layer stack comprising an alternating sequence of lower sacrificial layers and channel layers, and a top sacrificial layer over the topmost channel layer, wherein the top sacrificial layer is thicker than each lower sacrificial layer; etching the top sacrificial layer to form a top sacrificial layer portion underneath the sacrificial gate structure; forming a first spacer on end surfaces of the top sacrificial layer portion; etching the channel and lower sacrificial layers while using the first spacer as an etch mask to form channel layer portions and lower sacrificial layer portions; etching the lower sacrificial layer portions to form recesses in the device layer stack, while the first spacer masks the end surfaces of the top sacrificial layer portion; and forming a second spacer in the recesses.

Provided are an electronic/optical device, which is reduced in contact resistance occurring between a layered material layer and a metal electrode layer, and a method of manufacturing the device. The electronic/optical device of the present invention includes a laminated structure in which an intermediate layer is arranged between a layered material layer (2) and a metal electrode layer (3). The intermediate layer is a crystal layer (4) of an intermediate layer-forming material containing: at least one of Sb and Bi; and Te. In addition, the method of manufacturing an electronic/optical device of the present invention includes: an intermediate layer-forming step of forming, on the layered material layer (2), the intermediate layer (crystal layer (4)) obtained by crystallizing an intermediate layer-forming material containing: at least one of Sb and Bi; and Te; and a metal electrode layer-forming step of forming the metal electrode layer (3) on the intermediate layer.

A fin-FET or other multi-gate transistor is disclosed. The transistor comprises a semiconductor substrate having a first lattice constant, and a semiconductor fin extending from the semiconductor substrate. The fin has a second lattice constant, different from the first lattice constant, and a top surface and two opposed side surfaces. The transistor also includes a gate dielectric covering at least a portion of the top surface and the two opposed side surfaces, and a gate electrode covering at least a portion of the gate dielectric. The resulting channel has a strain induced therein by the lattice mismatch between the fin and the substrate. This strain can be tuned by selection of the respective materials.