Abstract: A CMOS circuit is provided that includes a PMOS transistor, an NMOS transistor adjacent the PMOS transistor in a channel width direction, a compressive stress liner overlying the PMOS transistor, and a tensile stress liner overlying the NMOS transistor. A portion of the compressive stress liner and a portion of the tensile stress liner are in a stacked configuration, and an overlap region of the compressive stress liner and the tensile stress liner is sufficient to result in an enhanced transverse stress in the compressive stress liner or the tensile stress liner.

Abstract: A stress enhanced MOS circuit is provided. The stress enhanced MOS circuit comprises a semiconductor substrate and a gate insulator overlying the semiconductor substrate. A gate electrode overlies the gate insulator; the gate electrode has side walls and comprising a layer of polycrystalline silicon having a first thickness in contact with the gate insulator and a layer of electrically conductive stressed material having a second thickness greater than the first thickness overlying the layer of polycrystalline silicon. A stress liner overlies the side walls of the gate electrode.

Abstract: A stress enhanced CMOS circuit and methods for its fabrication are provided. One fabrication method comprises the steps of forming an NMOS transistor and a PMOS transistor adjacent the NMOS transistor in a channel width direction, the PMOS transistor and the NMOS transistor separated by an isolation region. A compressive stress liner is deposited overlying the transistors and the isolation region and is etched to remove the compressive stress liner from the NMOS transistor and from a portion of the isolation region. A tensile stress liner is deposited overlying the transistors, the isolation region, and the compressive stress liner and is etched to remove a portion of the tensile stress liner overlying a portion of the compressive stress liner and to leave the tensile stress liner overlying the NMOS transistor, the isolation region, and a portion of the compressive stress liner.

Abstract: A stress enhanced MOS circuit and methods for its fabrication are provided. The stress enhanced MOS circuit comprises a semiconductor substrate and a gate insulator overlying the semiconductor substrate. A gate electrode overlies the gate insulator; the gate electrode has side walls and comprising a layer of polycrystalline silicon having a first thickness in contact with the gate insulator and a layer of electrically conductive stressed material having a second thickness greater than the first thickness overlying the layer of polycrystalline silicon. A stress liner overlies the side walls of the gate electrode.

Abstract: A method for improving channel carrier mobility in ultra-thin Silicon-on-oxide (UTSOI) FET devices by integrating an embedded pFET SiGe extension with raised source/drain regions. The method includes selectively growing embedded SiGe (eSiGe) extensions in pFET regions and forming strain-free raised Si or SiGe source/drain (RSD) regions on CMOS. The eSiGe extension regions enhance hole mobility in the pFET channels and reduce resistance in the pFET extensions. The strain-free raised source/drain regions reduce contact resistance in both UTSOI pFETs and nFETs.

Abstract: Methods are provided for fabricating a stress enhanced MOS circuit. One method comprises the steps of depositing a stressed material overlying a semiconductor substrate and patterning the stressed material to form a stressed dummy gate electrode overlying a channel region in the semiconductor substrate so that the stressed dummy gate induces a stress in the channel region. Regions of the semiconductor substrate adjacent the channel are processed to maintain the stress to the channel region and the stressed dummy gate electrode is replaced with a permanent gate electrode.

Abstract: A stress enhanced CMOS circuit and methods for its fabrication are provided. One fabrication method comprises the steps of forming an NMOS transistor and a PMOS transistor adjacent the NMOS transistor in a channel width direction, the PMOS transistor and the NMOS transistor separated by an isolation region. A compressive stress liner is deposited overlying the transistors and the isolation region and is etched to remove the compressive stress liner from the NMOS transistor and from a portion of the isolation region. A tensile stress liner is deposited overlying the transistors, the isolation region, and the compressive stress liner and is etched to remove a portion of the tensile stress liner overlying a portion of the compressive stress liner and to leave the tensile stress liner overlying the NMOS transistor, the isolation region, and a portion of the compressive stress liner.

Abstract: Methods are provided for fabricating a stress enhanced MOS circuit. One method comprises the steps of depositing a stressed material overlying a semiconductor substrate and patterning the stressed material to form a stressed dummy gate electrode overlying a channel region in the semiconductor substrate so that the stressed dummy gate induces a stress in the channel region. Regions of the semiconductor substrate adjacent the channel are processed to maintain the stress to the channel region and the stressed dummy gate electrode is replaced with a permanent gate electrode.

Abstract: A stress enhanced MOS circuit and methods for its fabrication are provided. The stress enhanced MOS circuit comprises a semiconductor substrate and a gate insulator overlying the semiconductor substrate. A gate electrode overlies the gate insulator; the gate electrode has side walls and comprising a layer of polycrystalline silicon having a first thickness in contact with the gate insulator and a layer of electrically conductive stressed material having a second thickness greater than the first thickness overlying the layer of polycrystalline silicon. A stress liner overlies the side walls of the gate electrode.