Abstract: A semiconductor substrate is provided having an insulator thereon with a semiconductor layer on the insulator. A deep trench isolation is formed, introducing strain to the semiconductor layer. A gate dielectric and a gate are formed on the semiconductor layer. A spacer is formed around the gate, and the semiconductor layer and the insulator are removed outside the spacer. Recessed source/drain are formed outside the spacer.

Abstract: A method of forming an abrupt junction device with a semiconductor substrate is provided. A gate dielectric is formed on a semiconductor substrate, and a gate is formed on the gate dielectric. A sidewall spacer is formed on the semiconductor substrate adjacent the gate and the gate dielectric. A thickening layer is formed by selective epitaxial growth on the semiconductor substrate adjacent the sidewall spacer. Raised source/drain dopant implanted regions are formed in at least a portion of the thickening layer. Silicide layers are formed in at least a portion of the raised source/drain dopant implanted regions to form source/drain regions, beneath the silicide layers, that are enriched with dopant from the silicide layers. A dielectric layer is deposited over the silicide layers, and contacts are then formed in the dielectric layer to the silicide layers.

Abstract: A semiconductor device is fabricated by providing a substrate, and providing a dielectric layer on the substrate. A polysilicon body is formed on the dielectric layer, and a metal layer is provided on the polysilicon body. A silicidation process is undertaken to silicidize substantially the entire polysilicon body to form a gate on the dielectric. In an alternative process, a cap layer is provided on the polysilicon body, which cap layer is removed prior to the silicidation process. The polysilicon body is doped with a chosen specie prior to the silicidation process, which dopant, during the silicidation process, is driven toward the dielectric layer to form a gate portion having a high concentration thereof adjacent the dielectric, the type and concentration of this specie being instrumental in determining the work function of the formed gate.

Abstract: A method of forming a channel region for a transistor includes forming a layer of silicon germanium (SiGe) above a substrate, forming an oxide layer above the SiGe layer wherein the oxide layer includes an aperture in a channel area and the aperture is filled with a SiGe feature, depositing a layer having a first thickness above the oxide layer and the SiGe feature, and forming source and drain regions in the layer.

Abstract: A method of forming a finFET transistor using a sidewall epitaxial layer includes forming a silicon germanium (SiGe) layer above an oxide layer above a substrate, forming a cap layer above the SiGe layer, removing portions of the SiGe layer and the cap layer to form a feature, forming sidewalls along lateral walls of the feature, and removing the feature.

Abstract: Methods for reducing the contact resistance presented by the interface between a silicide and a doped silicon region are presented. In a first method, a silicide layer and a doped silicon region form an interface. Either a damage-only species or a heavy, metal is implanted through the silicide layer into the doped silicon region immediately adjacent the interface. In a second method, a second metal is added to the refractory metal before formation of the silicide. After annealing the refractory metal and the doped silicon region, the second metal diffuses into the doped silicion region immediately adjacent the interface without forming additional phases in the silicide.

Abstract: A semiconductor device is fabricated by providing a substrate, and providing a dielectric layer on the substrate. A polysilicon body is formed on the dielectric layer, and a metal layer is provided on the polysilicon body. A silicidation process is undertaken to silicidize substantially the entire polysilicon body to form a gate on the dielectric. In an alternative process, a cap layer is provided on the polysilicon body, which cap layer is removed prior to the silicidation process. The polysilicon body is doped with a chosen specie prior to the silicidation process, which dopant, during the silicidation process, is driven toward the dielectric layer to form a gate portion having a high concentration thereof adjacent the dielectric, the type and concentration of this specie being instrumental in determining the work function of the formed gate.

Abstract: A semiconductor device is fabricated by providing a substrate, and providing a dielectric layer on the substrate. A polysilicon body is formed on the dielectric layer, and a metal layer is provided on the polysilicon body. A silicidation process is undertaken to silicidize substantially the entire polysilicon body to form a gate on the dielectric. In an alternative process, a cap layer is provided on the polysilicon body, which cap layer is removed prior to the silicidation process. The polysilicon body is doped with a chosen specie prior to the silicidation process, which dopant, during the silicidation process, is driven toward the dielectric layer to form a gate portion having a high concentration thereof adjacent the dielectric, the type and concentration of this specie being instrumental in determining the work function of the formed gate.

Abstract: A method for providing partially depleted and fully depleted transistor devices on the same semiconductor wafer. At least one trench is etched into a bulk semiconductor wafer. The wafer is then filled with an insulating material and polished down to the surface level of the semiconductor wafer to form a generally planar surface. A handle wafer is provided having a substrate layer and an insulating layer. The planar surface of the semiconductor wafer is bonded to the insulating layer of the handle wafer. The trench filled regions of the semiconductor wafer form regions of a first thickness and the remaining regions of the semiconductor wafer form regions of a second thickness. Fully depleted transistor device can then be formed in the regions of the first thickness and partially depleted transistor devices can be formed in regions of the second thickness.

Abstract: A low thermal budget transistor is fabricated by first forming a gate on a semiconductor substrate. First amorphous regions and first inactive dopant regions are then created in the substrate by ion implantation. Sidewall spacers, which align subsequent implantation steps, are formed adjacent to the gate. Thereafter, second amorphous regions and second inactive dopant regions are created in the substrate by ion implantation. Dopants in the first and second inactive dopant regions are then activated using a low temperature annealing process to create source/drain regions and source/drain extension regions. The aforementioned process simplifies the fabrication of a low thermal budget transistor by dispensing with the requirement to remove the sidewall spacers.

Abstract: A method of manufacturing an accumulation mode n-channel Silicon On Insulator (SOI) transistor includes forming an intrinsic silicon body region implanted with two deep Boron and one shallow Phosphorous implants; forming source/drain regions each implanted with Arsenic; and forming p-type regions adjacent each of the source and drain regions and disposed along the transistor channel. The SOI transistor has a higher transconductance than known SOI devices.

Abstract: A design for an MOS transistor deliberately uses depletion in a polysilicon gate electrode to improve circuit performance. Conventional transistor design seeks to minimize depletion in a polysilicon gate electrode to increase drive current. According to an embodiment of the present invention, appropriate levels of depletion in the gate electrode, larger than conventional levels, simultaneously provide desired drive current while minimizing circuit delay. According to another aspect, circuit performance is improved by adjusting doping levels in the channel region to maintain a threshold voltage at the same level as that which is achieved with minimum depletion in a polysilicon gate electrode. A method of fabricating an MOS device including a polysilicon gate electrode with increased depletion is also provided.

Abstract: A silicon-on-insulator MOSFET includes a silicon layer and an insulator layer positioned over a silicon substrate. An isolation region defines a silicon region positioned over the insulator layer. The silicon region further includes a source region, a drain region, and a doped body region. The drain region and source region do not extend to the bottom of the silicon region. A first metal conductor is electrically coupled to the side and top of the source region and the side of the body region. The first metal conductor establishes a potential at the body region to control floating body effects. A second metal conductor is electrically coupled to the top of the drain region.