Abstract: A method (and structure) for an electronic chip having at least one layer of material for which a carrier mobility of a first carrier type is higher in a first crystal surface than in a second crystal surface and for which a carrier mobility of a second carrier type is higher in the second crystal surface than the first crystal surface includes a first device having at least one component fabricated on the first crystal surface of the material, wherein an activity of the component of the first device involves primarily the first carrier type, and a second device having at least one component fabricated on the second crystal surface of the material, wherein an activity of the component of the second device involves primarily the second carrier type.

Abstract: A MOS structure processed to have a semiconductor-dielectric interface that is passivated to reduce the interface state density. An example is a MOSFET having a gate dielectric on which an electrode is present that is substantially impervious to molecular hydrogen, but sufficiently thin to be pervious to atomic hydrogen, enabling atomic hydrogen to be diffused therethrough into an underlying semiconductor-dielectric interface. Atomic hydrogen diffusion can be achieved by subjecting such an electrode to hydrogen plasma, forming the electrode of an aluminum-tungsten alloy in the presence of hydrogen, and implanting atomic hydrogen into the electrode. The latter two techniques are each followed by an anneal to cause the atomic hydrogen to diffuse through the electrode and into the semiconductor-dielectric interface.

Abstract: A process for passivating the semiconductor-dielectric interface of a MOS structure to reduce the interface state density to a very low level. A particular example is a MOSFET having a tungsten electrode that in the past has prevented passivation of the underlying semiconductor-dielectric interface to an extent sufficient to reduce the interface state density to less than 5x1010/cm2-eV. Though substantially impervious to molecular hydrogen, thin tungsten layers are shown to be pervious to atomic hydrogen, enabling atomic hydrogen to be diffused through a tungsten electrode into an underlying semiconductor-dielectric interface.

Abstract: A method of treating structures (and the structure formed thereby), so as to prevent or retard the oxidation of a metal film, and/or prevent its delamination a substrate, includes providing a structure including a refractory metal film formed on a substrate, placing the structure into a vessel having a base pressure below approximately 10−7 torr, exposing the structure to a silane gas at a sufficiently high predetermined temperature and predetermined pressure to cause formation of a metal silicide layer on the refractory metal film, and exposing the structure to a second gas at a sufficiently high temperature and pressure to nitride the metal silicide layer into a nitrided layer.

Abstract: A double-gate field effect transistor (DGFET) is provided using a damascene-like replacement gate processing step to create sidewall source/drain regions, oxide spacers and gate structures inside a previously formed trench. The damascene-like replacement gate processing step allows for the fabrication of a tapered transistor body region having a thicker body under the contacts which reduces access resistance.

Abstract: A method (and resultant structure) of forming a semiconductor device, includes forming a metal-back-gate over a substrate and a metal back-gate, forming a passivation layer on the metal back-gate to prevent the metal back-gate from reacting with radical species, and providing an intermediate gluing layer between the substrate and the metal back-gate to enhance adhesion.

Abstract: The present invention relates to a method of reducing Si consumption during a self-aligned silicide process which employs a M—Si or M—Si—Ge alloy, where M is Co, Ni or CoNi and a blanket layer of Si. The present invention is particularly useful in minimizing Si consumption in shallow junction and thin silicon-on-insulator (SOI) electronic devices.

Abstract: The present invention relates to a method of reducing Si consumption during a self-aligned silicide process which employs a M—Si or M—Si—Ge alloy, where M is Co, Ni or CoNi, and a blanket layer of Si. The present invention is particularly useful in minimizing Si consumption in shallow junction and thin silicon-on-insulator (SOI) electronic devices.

Abstract: Active devices that have either a thread or a ribbon geometry. The thread geometry includes single thread active devices and multiple thread devices. Single thread devices have a central core that may contain different materials depending upon whether the active device is responsive to electrical, light, mechanical, heat, or chemical energy. Single thread active devices include FETs, electro-optical devices, stress transducers, and the like. The active devices include a semiconductor body that for the single thread devices is a layer about the core of the thread. For the multiple thread devices, the semiconductor body is either a layer on one or more of the threads or an elongated body disposed between two of the threads. For example, a FET is formed of three threads, one of which carries a gate insulator layer and a semiconductor layer and the other two of which are electrically conductive and serve as the source and drain. The substrates or threads are preferably flexible and can be formed in a fabric.

Abstract: A process for passivating the semiconductor-dielectric interface of a MOS structure to reduce the interface state density to a very low level. A particular example is a MOSFET having a tungsten electrode that in the past has prevented passivation of the underlying semiconductor-dielectric interface to an extent sufficient to reduce the interface state density to less than 5×1010/cm2-eV. Though substantially impervious to molecular hydrogen, thin tungsten layers are shown to be pervious to atomic hydrogen, enabling atomic hydrogen to be diffused through a tungsten electrode into an underlying semiconductor-dielectric interface.

Abstract: A method of manufacturing a metal-oxide-semiconductor field effect transistor MOSFET device gate includes patterning and etching the mesa of a gate material. A dielectric layer is formed on the mesa and is planarized using chemical mechanical polishing (CMP). The active gate dimension is patterned and etched to form source and drain wells that extend down to an active area on either side of the MOSFET gate. In one further embodiment, the wells are filled with metal and the metal is planarized. The MOSFET device, in one embodiment, includes source and drain wells equally spaced from the active gate.

Abstract: A method of forming a double gate metal-oxide-semiconductor field effect transistor (MOSFET). The method includes planarizing a backgate mesa stack of a backgate using chemical mechanical polishing (CMP) to isolate the backgate mesa. A topgate mesa stack is formed and patterned. The backgate is trimmed using the topgate as a mask to transfer a topgate pattern to the backgate. Then, the trimmed backgate is isolated. In one particular embodiment, CMP is used to isolate and planarize the trimmed backgate.

Abstract: A method of manufacturing a metal-oxide-semiconductor field effect transistor MOSFET device gate includes patterning and etching the mesa of a gate material. A dielectric layer is formed on the mesa and is planarized using chemical mechanical polishing (CMP). The active gate dimension is patterned and etched to form source and drain wells that extend down to an active area on either side of the MOSFET gate. In one further embodiment, the wells are filled with metal and the metal is planarized. The MOSFET device, in one embodiment, includes source and drain wells equally spaced from the active gate.

Abstract: A method of treating structures (and the structure formed thereby), so as to prevent or retard the oxidation of a metal film, and/or prevent its delamination a substrate, includes providing a structure including a refractory metal film formed on a substrate, placing the structure into a vessel having a base pressure below approximately 10−7 torr, exposing the structure to a silane gas at a sufficiently high predetermined temperature and predetermined pressure to cause formation of a metal silicide layer on the refractory metal film, and exposing the structure to a second gas at a sufficiently high temperature and pressure to nitride the metal silicide layer into a nitrided layer.

Abstract: A method of treating structures (and the structure formed thereby), so as to prevent or retard the oxidation of a metal film, and/or prevent its delamination a substrate, includes providing a structure including a refractory metal film formed on a substrate, placing the structure into a vessel having a base pressure below approximately 10−7 torr, exposing the structure to a silane gas at a sufficiently high predetermined temperature and predetermined pressure to cause formation of a metal silicide layer on the refractory metal film, and exposing the structure to a second gas at a sufficiently high temperature and pressure to nitride the metal silicide layer into a nitrided layer.

Abstract: An energy saving clock signal generator is disclosed including a source of multi-phase waveform signals, a shift register, and a matrix switch. The waveform source provide four, six or more waveform signals to the shift register and the matrix switch. A number of progressive pulses N.sub.pp which are an integer multiple of the number of waveform signals are applied from the shift register to the matrix switch. The matrix switch responds to the waveform signals and the progressive pulse signals to produce a number of output clock signals which may be used to drive adiabatic logic circuits.

Abstract: A doped or undoped photoresponsive material having metallic precipitates, and a PiN photodiode utilizing the material for detecting light having a wavelength of 1.3 micrometers. The PiN photodiode includes a substrate having a first compound semiconductor layer disposed thereon. The PiN photodiode further includes an optically responsive compound semiconductor layer disposed above the first compound semiconductor layer. The optically responsive layer includes a plurality of buried Schottky barriers, each of which is associated with an inclusion within a crystal lattice of a Group III-V material. The PiN device also includes a further compound semiconductor layer disposed above the optically responsive layer. For a transversely illuminated embodiment, waveguiding layers may also be disposed above and below the PiN structure. In one example the optically responsive layer is comprised of GaAs:As.

Abstract: A doped or undoped photoresponsive material having metallic precipitates, and a PiN photodiode utilizing the material for detecting light having a wavelength of 1.3 micrometers. The PiN photodiode includes a substrate having a first compound semiconductor layer disposed thereon. The PiN photodiode further includes an optically responsive compound semiconductor layer disposed above the first compound semiconductor layer. The optically responsive layer includes a plurality of buried Schottky barriers, each of which is associated with an inclusion within a crystal lattice of a Group III-V material. The PiN device also includes a further compound semiconductor layer disposed above the optically responsive layer. For a transversely illuminated embodiment, waveguiding layers may also be disposed above and below the PiN structure. In one example the optically responsive layer is comprised of GaAs:As.

Abstract: An alloy layer comprising germanium and silicon is grown on top of a silicon substrate. The alloy layer is kept thin enough for proper pseudomorphic, dislocation free growth. A layer of silicon is applied to the alloy layer. The initial silicon layer is from two to three times as thick as the alloy layer. Approximately the upper two-thirds of the silicon layer is oxidized, either thermally, anodically or by plasma anodization. The silicon layer that remains between the silicon dioxide and the alloy layer is kept thin enough so that a parasitic channel does not form on the interface between the silicon and the silicon dioxide. The germanium alloyed channel is thus suitably bounded by silicon crystalline structures on both of the channel layer surfaces. The barrier heights between silicon dioxide and silicon are very large thus providing good carrie confinement.

Abstract: A new gallium arsenide gate heterojunction FET is disclosed. The gate is a multi-layer structure including an intermediate carrier depletable layer. Upon applying a gate voltage, the intermediate layer becomes depleted thereby effectively increasing the gate resistance and reducing gate leakage current.