Abstract: A method for manufacturing a semiconductor device comprises growing a source/drain epitaxy region over a plurality of gates on a substrate, wherein a top surface of the source/drain epitaxy region is at a height above a top surface of each of the plurality of gates, forming at least one opening in the source/drain epitaxy region over a top surface of at least one gate, forming a silicide layer on the source/drain epitaxy region, wherein the silicide layer lines lateral sides of the at least one opening, depositing a dielectric layer on the silicide layer, wherein the dielectric layer is deposited in the at least one opening between the silicide layer on lateral sides of the at least one opening, etching the dielectric layer to form a contact area, and depositing a conductor in the contact area.

Abstract: A method for manufacturing a semiconductor device, comprises forming an organic planarization layer on a plurality of gates on a substrate, wherein the plurality of gates each include a spacer layer thereon, forming an oxide layer on the organic planarization layer, removing a portion of the oxide layer to expose the organic planarization layer, stripping the organic planarization layer to form a cavity, patterning a direct lithographically-patternable gap dielectric on at least one of the gates in the cavity, and depositing a conductive contact in a remaining portion of the cavity.

Abstract: Field Effect Transistors (FETs), Integrated Circuit (IC) chips including the FETs, and a method of forming the FETs and IC. FET locations and adjacent source/drain regions are defined on a semiconductor wafer, e.g., a silicon on insulator (SOI) wafer. Source/drains are formed in source/drains regions. A stopping layer is formed on source/drains. Contact spacers are formed above gates. Source/drain contacts are formed to the stopping layer, e.g., after converting the stopping layer to silicide. The contact spacers separate source/drain contacts from each other.

Abstract: A method for forming a device with a multi-tiered contact structure includes forming first contacts in via holes down to a first level, forming a dielectric capping layer over exposed portions of the first contacts and forming a dielectric layer over the capping layer. Via holes are opened in the dielectric layer down to the capping layer. Holes are opened in the capping layer through the via holes to expose the first contacts. Contact connectors and second contacts are formed in the via holes such that the first and second contacts are connected through the capping layer by the contact connectors to form multi-tiered contacts.

Abstract: A photo-patternable dielectric material is provided to a structure which includes a substrate having at least one gate structure. The photo-patternable dielectric material is then patterned forming a plurality of sacrificial contact structures adjacent the at least one gate structure. A planarized middle-of-the-line dielectric material is then provided in which an uppermost surface of each of the sacrificial contact structures is exposed. Each of the exposed sacrificial contact structures is then removed providing contact openings within the planarized middle-of-the-line dielectric material. A conductive metal-containing material is formed within each contact opening.

Abstract: A photo-patternable dielectric material is provided to a structure which includes a substrate having at least one gate structure. The photo-patternable dielectric material is then patterned forming a plurality of sacrificial contact structures adjacent the at least one gate structure. A planarized middle-of-the-line dielectric material is then provided in which an uppermost surface of each of the sacrificial contact structures is exposed. Each of the exposed sacrificial contact structures is then removed providing contact openings within the planarized middle-of-the-line dielectric material. A conductive metal-containing material is formed within each contact opening.

Abstract: At least one gate structure having a first spacer located on a vertical sidewall thereof is provided on an uppermost surface of a semiconductor substrate. Exposed portions of the semiconductor substrate are then removed utilizing the at least one gate structure and first spacer as an etch mask. A sacrificial replacement material is formed on each recessed surface of the semiconductor substrate. Next, a second spacer is formed contacting the first spacer. Source/drain trenches are then provided by removing exposed portions of the sacrificial replacement material and an underlying portion of the semiconductor substrate. Remaining sacrificial replacement material located beneath the second spacer is removed providing an opening beneath the second spacer. A doped semiconductor material is formed within the source/drain trenches and the opening.

Abstract: The invention discloses a method for forming an interfacial passivation layer on the Ge semiconductor. The supercritical CO2 fluids is used to form an interfacial passivation layer between Ge channel and gate insulator layer, and improve the dielectric characteristics of gate insulator after high-temperature thermal annealing process.