Abstract: The present invention relates generally to semiconductor devices and more particularly, to a structure and method of forming an abrupt junction in the channel regions of high density technologies, such as tight pitch FinFET devices, using recessed source-drain (S-D) regions and annealing techniques. In an embodiment, a faceted buffer layer, deposited before the S-D region is formed, may be used to control the profile and dopant concentration of the junction under the channel. In another embodiment, the profile and dopant concentration of the junction may be controlled via a dopant concentration gradient in the S-D region.

Abstract: Embodiments of the present invention provide a method for epitaxially growing a FinFET. One method may include providing a semiconductor substrate including an insulator and an underlayer; forming a channel layer on the semiconductor substrate using epitaxial growth; etching a recess into the channel layer and epitaxially regrowing a portion on the channel layer; etching the channel layer and the underlayer to form fins; forming a gate structure and a set of spacers; etching a source drain region into the channel layer; and forming a source drain material in the source drain region.

Abstract: A gate structure is formed straddling a first portion of a plurality of semiconductor fins that extend upwards from a topmost surface of an insulator layer. A dielectric spacer is formed on sidewalls of the gate structure and straddling a second portion of the plurality of semiconductor fins. Epitaxial semiconductor material portions that include a non-planar bottommost surface and a non-planar topmost surface are grown from at least the exposed sidewalls of each semiconductor fin not including the gate structure or the gate spacer to merge adjacent semiconductor fins. A gap is present beneath epitaxial semiconductor material portions and the topmost surface of the insulator layer. A second epitaxial semiconductor material is formed on the epitaxial semiconductor material portions and thereafter the second epitaxial semiconductor material is converted into a metal semiconductor alloy.

Abstract: A gate structure is formed straddling a first portion of a plurality of semiconductor fins that extend upwards from a topmost surface of an insulator layer. A dielectric spacer is formed on sidewalls of the gate structure and straddling a second portion of the plurality of semiconductor fins. Epitaxial semiconductor material portions that include a non-planar bottommost surface and a non-planar topmost surface are grown from at least the exposed sidewalls of each semiconductor fin not including the gate structure or the gate spacer to merge adjacent semiconductor fins. A gap is present beneath epitaxial semiconductor material portions and the topmost surface of the insulator layer. A second epitaxial semiconductor material is formed on the epitaxial semiconductor material portions and thereafter the second epitaxial semiconductor material is converted into a metal semiconductor alloy.

Abstract: The present invention relates generally to semiconductor devices and more particularly, to a structure and method of forming an abrupt junction in the channel regions of high density technologies, such as tight pitch FinFET devices, using recessed source-drain (S-D) regions and annealing techniques. In an embodiment, a faceted buffer layer, deposited before the S-D region is formed, may be used to control the profile and dopant concentration of the junction under the channel. In another embodiment, the profile and dopant concentration of the junction may be controlled via a dopant concentration gradient in the S-D region.

Abstract: A method forming a semiconductor device that in one embodiment includes forming a gate structure on a channel region of fin structures, and forming a flowable dielectric material on a source region portion and a drain region portion of the fin structures. The flowable dielectric material is present at least between adjacent fin structures of the plurality of fin structures filling a space between the adjacent fin structures. An upper surface of the source region portion and the drain region portion of fin structures is exposed. An epitaxial semiconductor material is formed on the upper surface of the source region portion and the drain region portion of the fin structures.

Abstract: The present invention relates generally to semiconductor devices and more particularly, to a structure and method of forming an abrupt junction in the channel regions of high density technologies, such as tight pitch FinFET devices, using recessed source-drain (S-D) regions and annealing techniques. In an embodiment, a faceted buffer layer, deposited before the S-D region is formed, may be used to control the profile and dopant concentration of the junction under the channel. In another embodiment, the profile and dopant concentration of the junction may be controlled via a dopant concentration gradient in the S-D region.

Abstract: A method for producing a semiconductor structure, as well as a semiconductor structure, that uses a partial removal of an insulating layer around a semiconductor fin, and subsequently epitaxially growing an additional semiconductor material in the exposed regions, while maintaining the shape of the fin with the insulating layer.

Abstract: Embodiments of the present invention provide a method for epitaxially growing a FinFET. One method may include providing a semiconductor substrate including an insulator and an underlayer; forming a channel layer on the semiconductor substrate using epitaxial growth; etching a recess into the channel layer and epitaxially regrowing a portion on the channel layer; etching the channel layer and the underlayer to form fins; forming a gate structure and a set of spacers; etching a source drain region into the channel layer; and forming a source drain material in the source drain region.

Abstract: A method forming a semiconductor device that in one embodiment includes forming a gate structure on a channel region of fin structures, and forming a flowable dielectric material on a source region portion and a drain region portion of the fin structures. The flowable dielectric material is present at least between adjacent fin structures of the plurality of fin structures filling a space between the adjacent fin structures. An upper surface of the source region portion and the drain region portion of fin structures is exposed. An epitaxial semiconductor material is formed on the upper surface of the source region portion and the drain region portion of the fin structures.

Abstract: A semiconductor structure may include a semiconductor fin, a gate over the semiconductor fin, a spacer on a sidewall of the gate, an angled recess region in an end of the semiconductor fin beneath the spacer, and a first semiconductor region filling the angled recess. The angled recess may be v-shaped or sigma shaped. The structure may further include a second semiconductor region in contact with the first semiconductor region and the substrate. The structure may be formed by forming a gate above a portion of the semiconductor fin on a substrate, forming a spacer on a sidewall of the gate; removing a portion of the semiconductor fin not covered by the spacer or the gate to expose a sidewall of the fin, etching the sidewall of the fin to form an angled recess region beneath the spacer, and filling the angled recess region with a first epitaxial semiconductor region.

Abstract: A gate structure is formed straddling a first portion of a plurality of semiconductor fins that extend upwards from a topmost surface of an insulator layer. A dielectric spacer is formed on sidewalls of the gate structure and straddling a second portion of the plurality of semiconductor fins. Epitaxial semiconductor material portions that include a non-planar bottommost surface and a non-planar topmost surface are grown from at least the exposed sidewalls of each semiconductor fin not including the gate structure or the gate spacer to merge adjacent semiconductor fins. A gap is present beneath epitaxial semiconductor material portions and the topmost surface of the insulator layer. A second epitaxial semiconductor material is formed on the epitaxial semiconductor material portions and thereafter the second epitaxial semiconductor material is converted into a metal semiconductor alloy.

Abstract: A gate structure is formed straddling a first portion of a plurality of semiconductor fins that extend upwards from a topmost surface of an insulator layer. A dielectric spacer is formed on sidewalls of the gate structure and straddling a second portion of the plurality of semiconductor fins. Epitaxial semiconductor material portions that include a non-planar bottommost surface and a non-planar topmost surface are grown from at least the exposed sidewalls of each semiconductor fin not including the gate structure or the gate spacer to merge adjacent semiconductor fins. A gap is present beneath epitaxial semiconductor material portions and the topmost surface of the insulator layer. A second epitaxial semiconductor material is formed on the epitaxial semiconductor material portions and thereafter the second epitaxial semiconductor material is converted into a metal semiconductor alloy.

Abstract: A semiconductor device including at least one suspended channel structure of a silicon including material, and a gate structure present on the suspended channel structure. At least one gate dielectric layer is present surrounding the suspended channel structure, and at least one gate conductor is present on the at least one gate dielectric layer. Source and drain structures may be composed of a silicon and germanium including material. The source and drain structures are in contact with the source and drain region ends of the suspended channel structure through a silicon cladding layer.

Abstract: A method forming a semiconductor device that in one embodiment includes forming a gate structure on a channel region of fin structures, and forming a flowable dielectric material on a source region portion and a drain region portion of the fin structures. The flowable dielectric material is present at least between adjacent fin structures of the plurality of fin structures filling a space between the adjacent fin structures. An upper surface of the source region portion and the drain region portion of fin structures is exposed. An epitaxial semiconductor material is formed on the upper surface of the source region portion and the drain region portion of the fin structures.

Abstract: A method of forming a semiconductor structure includes forming a first fin and a second fin on a substrate. A gate structure is formed over a first portion of the first fin and the second fin without covering a second portion of the first fin and the second fin. Single-crystal epitaxial layers are deposited surrounding the second portion of the first fin and the second fin such that the single-crystal epitaxial layer on the first fin does not contact the single-crystal epitaxial layer on the second fin. A polycrystalline layer is then deposited surrounding the single-crystal epitaxial layers, so that the polycrystalline layer contacts the single-crystal epitaxial layer on the first fin and the single-crystal epitaxial layer on the second fin. The single-crystal epitaxial layers and the polycrystalline layer form a merged source-drain region.

Abstract: A method of forming a semiconductor structure includes forming a first fin and a second fin on a substrate. A gate structure is formed over a first portion of the first fin and the second fin without covering a second portion of the first fin and the second fin. Single-crystal epitaxial layers are deposited surrounding the second portion of the first fin and the second fin such that the single-crystal epitaxial layer on the first fin does not contact the single-crystal epitaxial layer on the second fin. A polycrystalline layer is then deposited surrounding the single-crystal epitaxial layers, so that the polycrystalline layer contacts the single-crystal epitaxial layer on the first fin and the single-crystal epitaxial layer on the second fin. The single-crystal epitaxial layers and the polycrystalline layer form a merged source-drain region.

Abstract: An electronic system, connection failure reporting system and related methods. An electronic system may include a passive component of a connector; a detecting unit configured to detect presence of an active component of the connector in at least three points not in the same line on the passive component of the connector; and a connection status determining unit configured to determine a connection status of said connector based upon detecting results of the at least three points on the passive component of the connector. A connection problem of the connector can be identified, including identification of the type of connection failure.

Abstract: A semiconductor structure may include a semiconductor fin, a gate over the semiconductor fin, a spacer on a sidewall of the gate, an angled recess region in an end of the semiconductor fin beneath the spacer, and a first semiconductor region filling the angled recess. The angled recess may be v-shaped or sigma shaped. The structure may further include a second semiconductor region in contact with the first semiconductor region and the substrate. The structure may be formed by forming a gate above a portion of the semiconductor fin on a substrate, forming a spacer on a sidewall of the gate; removing a portion of the semiconductor fin not covered by the spacer or the gate to expose a sidewall of the fin, etching the sidewall of the fin to form an angled recess region beneath the spacer, and filling the angled recess region with a first epitaxial semiconductor region.

Abstract: A self-limiting selective epitaxy process can be employed on a plurality of semiconductor fins such that the sizes of raised active semiconductor regions formed by the selective epitaxy process are limited to dimensions determined by the sizes of the semiconductor fins. Specifically, the self-limiting selective epitaxy process limits growth of the semiconductor material along directions that are perpendicular to crystallographic facets formed during the selective epitaxy process. Once the crystallographic facets become adjoined to one another or to a dielectric surface, growth of the semiconductor material terminates, thereby preventing merger among epitaxially deposited semiconductor materials.