Abstract: The embodiments of the invention provide a device, method, etc. for a dual stress STI. A semiconductor device is provided having a substrate with a first transistor region and a second transistor region different than the first transistor region. The first transistor region includes a PFET; and, the second transistor region includes an NFET. Further, STI regions are provided in the substrate adjacent sides of and positioned between the first transistor region and the second transistor region, wherein the STI regions each include a compressive region, a compressive liner, a tensile region, and a tensile liner.

Abstract: Methods of forming integrated circuit devices include forming a field effect transistor having a gate electrode, sacrificial nitride spacers on opposing sidewalls of the gate electrode and source/drain regions, which are self-aligned to the sacrificial nitride spacers, on a semiconductor substrate. The sacrificial nitride spacers are selectively removed using a diluted hydrofluoric acid solution having a nitride-to-oxide etching selectivity in excess of one. In order to increase charge carrier mobility within a channel of the field effect transistor, a stress-inducing electrically insulating layer is formed on opposing sidewalls of the gate electrode. This insulating layer is configured to induce a net tensile stress (NMOS) or compressive stress (PMOS) in the channel.

Abstract: Disclosed herein is a semiconducting device comprising a gate stack formed on a surface of a semiconductor substrate; a vertical nitride spacer element formed on each vertical sidewall of the gate stack; a portion of the vertical nitride spacer overlying the semiconductor substrate; a silicide contact formed on the semiconductor substrate adjacent the gate stack, the silicide contact being in operative communication with drain and source regions formed in the semiconductor substrate; and an oxide spacer disposed between the vertical nitride spacer element and the silicide contact; the oxide spacer operating to minimize an undercut adjacent the vertical nitride spacer during an etching process.

Abstract: A method forms a first layer over a second layer that comprises silicon. A mask is formed and patterned over the insulator layer. Then, a heavy inert gas such as Xenon (Xe) is implanted through the openings in the mask, through the insulator layer, and into the regions of the silicon layer that are below the opening in the mask. The portions of the insulator layer that are below the openings in the mask are etched away and the mask is removed. A metal or metal alloy layer is formed over the first layer and the exposed regions of the second layer. At least the second layer is heated in a silicide process such that the metal and the exposed regions of the second layer combine to form silicide regions. After this, any remaining metal material can be removed to remove to leave the silicide regions adjacent non-silicide regions of the second layer.

Abstract: Semiconductor devices and methods of manufacturing thereof are disclosed. In a preferred embodiment, a method of manufacturing a semiconductor device includes providing a workpiece, and forming a recess in the workpiece. The recess has a depth having a first dimension. A first semiconductive material is formed in the recess to partially fill the recess in a central region to a height having a second dimension. The second dimension is about one-half or greater of the first dimension. A second semiconductive material is formed over the first semiconductive material in the recess to completely fill the recess, the second semiconductive material being different than the first semiconductive material.

Abstract: A method of fabricating a bottle trench and a bottle trench capacitor. The method including: providing a substrate; forming a trench in the substrate, the trench having sidewalls and a bottom, the trench having an upper region adjacent to a top surface of the substrate and a lower region adjacent to the bottom of the trench; forming an oxidized layer of the substrate in the bottom region of the trench; and removing the oxidized layer of the substrate from the bottom region of the trench, a cross-sectional area of the lower region of the trench greater than a cross-sectional area of the upper region of the trench.

Abstract: The embodiments of the invention provide a device, method, etc. for a dual stress STI. A semiconductor device is provided having a substrate with a first transistor region and a second transistor region different than the first transistor region. The first transistor region comprises a PFET; and, the second transistor region comprises an NFET. Further, STI regions are provided in the substrate adjacent sides of and positioned between the first transistor region and the second transistor region, wherein the STI regions each comprise a compressive region, a compressive liner, a tensile region, and a tensile liner.

Abstract: The present invention provides structures and methods for providing multiple parallel V-shaped faceted grooves with sub-lithographic widths on a semiconductor substrate for enhanced performance MOSFETs. A self-aligning self-assembling material is used to pattern multiple parallel sub-lithographic lines. By employing an anisotropic etch that produces crystallographic facets on a semiconductor surface, multiple adjoining parallel V-shaped grooves with sub-lithographic groove widths are formed. While providing enhanced mobility for the MOSFET, the width of the MOSFET is not limited by the depth of focus in subsequent lithographic steps or the thickness of semiconductor layer above a BOX layer due to the sub-lithographic widths of the V-shaped grooves and the consequent reduction in the variation of the vertical profile. Also, the MOSFET has a well defined threshold voltage due to the narrow widths of each facet.

Abstract: The embodiments of the invention provide a device, method, etc. for a dual stress STI. A semiconductor device is provided having a substrate with a first transistor region and a second transistor region different than the first transistor region. The first transistor region comprises a PFET; and, the second transistor region comprises an NFET. Further, STI regions are provided in the substrate adjacent sides of and positioned between the first transistor region and the second transistor region, wherein the STI regions each comprise a compressive region, a compressive liner, a tensile region, and a tensile liner.

Abstract: A MOSFET formed using asymmetric silicidation between source and drain induces higher leakage between the body and the source than between the body and the drain. Implementation of such a MOSFET on an SOI substrate reduces or eliminates floating body effect for consistent on-current and turn-on time. The asymmetry between the source and the drain is introduced by forming different silicides between the source and the drains with a thicker silicide on the source, or by recessing the source material so that the source silicide is formed closer to the buried oxide layer than the drain silicide.

Abstract: A method of fabricating a bottle trench and a bottle trench capacitor. The method including: providing a substrate; forming a trench in the substrate, the trench having sidewalls and a bottom, the trench having an upper region adjacent to a top surface of the substrate and a lower region adjacent to the bottom of the trench; forming an oxidized layer of the substrate in the bottom region of the trench; and removing the oxidized layer of the substrate from the bottom region of the trench, a cross-sectional area of the lower region of the trench greater than a cross-sectional area of the upper region of the trench.

Abstract: In a method of making a semiconductor device, a recess is formed in an upper surface of the semiconductor body of a first material. An embedded semiconductor region is formed in the recess. The embedded semiconductor region is formed from a second semiconductor material that is different than the first semiconductor material. An upper surface of the embedded semiconductor region is amorphized to create an amorphous region. A silicide is then formed over the amorphous region.

Abstract: A method of forming silicide contacts for a complementary metal oxide semiconductor (CMOS) device includes selectively forming a protective layer over faceted surfaces of an embedded SiGe (eSiGe) region of a substrate, the eSiGe region comprising a compressive stress inducing layer in a PFET portion of the CMOS device, wherein the faceted surfaces are disposed adjacent shallow trench isolation (STI) regions used to separate NFET regions from PFET regions of the CMOS device; depositing a metal layer for silicide formation over the CMOS device; and annealing the CMOS device to form silicide, wherein the protective layer formed over the faceted surfaces prevents the formation of silicide thereon.

Abstract: Structures having an isolation structure including deuterium and a related method are disclosed. The deuterium is preferably substantially uniformly distributed, and has a concentration (based on total hydrogen atom content) greater than that found in naturally occurring hydrogen. One structure includes a substrate for a semiconductor device including an isolation structure within the substrate, the isolation structure including substantially uniformly distributed deuterium in a concentration (based on total hydrogen atom content) greater than that found in naturally occurring hydrogen. The substrate may include a semiconductor-on-insulator substrate. A method may include the steps of: providing an isolation structure in a substrate, the isolation structure including deuterium; and annealing to diffuse the deuterium into the substrate (prior to and/or after forming a gate dielectric). The structures and method provide a more efficient means for incorporating deuterium and reducing defects.

Abstract: A method and device for increasing pFET performance without degradation of nFET performance. The method includes forming a first structure on a substrate using a first plane and direction and forming a second structure on the substrate using a second plane and direction. In use, the device includes a nFET stack on a substrate using a first plane and direction, e.g., (100)<110> and a pFET stack on the substrate using a second plane and direction, e.g., (111)/<112>. An isolation region within the substrate is provided between the nFET stack and the pFET stack.

Abstract: A DRAM cell in a substrate has a deep trench (DT) extending from a surface of the substrate into the substrate, a word line (WL) formed on the surface of the substrate adjacent the deep trench, and oxide (TTO) disposed in a top portion of the trench and extending beyond the trench in the direction of the word line. In this manner, when silicided, there is oxide rather than silicon on the surface of the substrate in a gap between the word line (WL) and a passing word line (PWL) disposed above the deep trench.

Abstract: A method and device for increasing pFET performance without degradation of nFET performance. The method includes forming a first structure on a substrate using a first plane and direction and forming a second structure on the substrate using a second plane and direction. In use, the device includes a nFET stack on a substrate using a first plane and direction, e.g., (100)<110> and a pFET stack on the substrate using a second plane and direction, e.g., (111)/<112>. An isolation region within the substrate is provided between the nFET stack and the pFET stack.

Abstract: The invention relates to a test structure and methods of detecting electrical defects between adjacent metal contacts using such test structure at the first metal level within a semiconductor device. The test structure includes dual first metal level comb structures each having extending lines that are in direct electrical communication with contacts residing in the semiconductor. The extending lines of the first metal comb are interlaced with extending lines on the second metal comb such that adjacent metal contacts are in electrical communication with different metal combs. In this manner, upon testing for electrical continuity, an electrical current passing from the first metal comb to the second metal comb indicates an electrical defect existing between adjacent metal contacts.

Abstract: A DRAM cell in a substrate has a deep trench (DT) extending from a surface of the substrate into the substrate, a word line (WL) formed on the surface of the substrate adjacent the deep trench, and oxide (TTO) disposed in a top portion of the trench and extending beyond the trench in the direction of the word line. In this manner, when silicided, there is oxide rather than silicon on the surface of the substrate in a gap between the word line (WL) and a passing word line (PWL) disposed above the deep trench.

Abstract: A method of fabricating a bottle trench and a bottle trench capacitor. The method including: providing a substrate; forming a trench in the substrate, the trench having sidewalls and a bottom, the trench having an upper region adjacent to a top surface of the substrate and a lower region adjacent to the bottom of the trench; forming an oxidized layer of the substrate in the bottom region of the trench; and removing the oxidized layer of the substrate from the bottom region of the trench, a cross-sectional area of the lower region of the trench greater than a cross-sectional area of the upper region of the trench.