Patent application number | Description | Published |
20080206958 | ENHANCEMENT OF ELECTRON AND HOLE MOBILITIES IN <110> Si UNDER BIAXIAL COMPRESSIVE STRAIN - The present invention provides a semiconductor material that has enhanced electron and hole mobilities that comprises a Si-containing layer having a <110> crystal orientation and a biaxial compressive strain. The term “biaxial compressive stress” is used herein to describe the net stress caused by longitudinal compressive stress and lateral stress that is induced upon the Si-containing layer during the manufacturing of the semiconductor material. Other aspect of the present invention relates to a method of forming the semiconductor material of the present invention. The method of the present invention includes the steps of providing a silicon-containing <110> layer; and creating a biaxial strain in the silicon-containing <110> layer. | 08-28-2008 |
20080286930 | NITRIDE-ENCAPSULATED FET (NNCFET) - A double-gate field effect transistor (DGFET) structure and method of forming such a structure in which the parasitic capacitance under the source/drain regions is substantially reduced are provided. In the present invention, self-aligned isolation regions are provided to reduce the parasitic capacitance in the DGFET structure. Additionally, the present invention encapsulates the silicon-containing channel layer to enable the back-gate to be oxidized to a greater extent thereby reducing the parasitic capacitance of the structure even further. | 11-20-2008 |
20080293246 | VERTICAL FET WITH NANOWIRE CHANNELS AND A SILICIDED BOTTOM CONTACT - A vertical FET structure with nanowire forming the FET channels is disclosed. The nanowires are formed over a conductive silicide layer. The nanowires are gated by a surrounding gate. Top and bottom insulator plugs function as gate spacers and reduce the gate-source and gate-drain capacitance. | 11-27-2008 |
20090124057 | DAMASCENE GATE FIELD EFFECT TRANSISTOR WITH AN INTERNAL SPACER STRUCTURE - A MOSFET is disclosed that comprises a channel between a source extension and a drain extension, a dielectric layer over the channel, a gate spacer structure formed on a peripheral portion of the dielectric layer, and a gate formed on a non-peripheral portion of the dielectric layer, with at least a lower portion of the gate surrounded by and in contact with an internal surface of the gate spacer structure, and the gate is substantially aligned at its bottom with the channel. One method of forming the MOSFET comprises forming the dielectric layer, the gate spacer structure and the gate contact inside a cavity that has been formed by removing a sacrificial gate and spacer structure. | 05-14-2009 |
20090311835 | NANOWIRE MOSFET WITH DOPED EPITAXIAL CONTACTS FOR SOURCE AND DRAIN - A FET structure with a nanowire forming the FET channel, and doped source and drain regions formed by radial epitaxy from the nanowire body is disclosed. A top gated and a bottom gated nanowire FET structures are discussed. The source and drain fabrication can use either selective or non-selective epitaxy. | 12-17-2009 |
20100047984 | SELF-ALIGNED METAL-SEMICONDUCTOR ALLOY AND METALLIZATION FOR SUB-LITHOGRAPHIC SOURCE AND DRAIN CONTACTS - A lateral double-gate FET structure with sub-lithographic source and drain regions is disclosed. The sub-lithographic source and drain regions are defined by a sacrificial spacer. Self-aligned metal-semiconductor alloy and metal contacts are made to the sub-lithographic source and drain using conventional silicon processing. | 02-25-2010 |
20110037175 | INTERCONNECTION BETWEEN SUBLITHOGRAPHIC-PITCHED STRUCTURES AND LITHOGRAPHIC-PITCHED STRUCTURES - An interconnection between a sublithographic-pitched structure and a lithographic pitched structure is formed. A plurality of conductive lines having a sublithographic pitch may be lithographically patterned and cut along a line at an angle less than 45 degrees from the lengthwise direction of the plurality of conductive lines. Alternately, a copolymer mixed with homopolymer may be placed into a recessed area and self-aligned to form a plurality of conductive lines having a sublithographic pitch in the constant width region and a lithographic dimension between adjacent lines at a trapezoidal region. Yet alternately, a first plurality of conductive lines with the sublithographic pitch and a second plurality of conductive lines with the lithographic pitch may be formed at the same level or at different. | 02-17-2011 |
20110049474 | TUNNEL FIELD EFFECT DEVICES - An indirectly induced tunnel emitter for a tunneling field effect transistor (TFET) structure includes an outer sheath that at least partially surrounds an elongated core element, the elongated core element formed from a first semiconductor material; an insulator layer disposed between the outer sheath and the core element; the outer sheath disposed at a location corresponding to a source region of the TFET structure; and a source contact that shorts the outer sheath to the core element; wherein the outer sheath is configured to introduce a carrier concentration in the source region of the core element sufficient for tunneling into a channel region of the TFET structure during an on state. | 03-03-2011 |
20110303950 | FABRICATION OF A VERTICAL HETEROJUNCTION TUNNEL-FET - Exemplary embodiments include a method for fabricating a heterojunction tunnel field-effect-transistor (FET), the method including forming a gate region on a silicon layer of a silicon-on-insulator (SOI) substrate, forming a drain region on the silicon layer adjacent the gate region and forming a vertical heterojunction source region adjacent the gate region, wherein the vertical heterojunction source region generates a tunnel path inline with a gate field associated with the gate region. | 12-15-2011 |
20120132989 | MULTIGATE STRUCTURE FORMED WITH ELECTROLESS METAL DEPOSITION - A multigate structure which comprises a semiconductor substrate; an ultra-thin silicon or carbon bodies of less than 20 nanometers thick located on the substrate; an electrolessly deposited metallic layer selectively located on the side surfaces and top surfaces of the ultra-thin silicon or carbon bodies and selectively located on top of the multigate structures to make electrical contact with the ultra-thin silicon or carbon bodies and to minimize parasitic resistance, and wherein the ultra-thin silicon or carbon bodies and metallic layer located thereon form source and drain regions is provided along with a process to fabricate the structure. | 05-31-2012 |
20120181928 | SOLID STATE KLYSTRON - A solid state Klystron structure is fabricated by forming a source contact and a drain contact to both ends of a conducting wire and by forming a bias gate and a signal gate on the conducting wire. The conducting wire may be at least one carbon nanotube or at least one semiconductor wire with long ballistic mean free paths. By applying a signal at a frequency that corresponds to an integer multiple of the transit time of the ballistic carriers between adjacent fingers of the signal gate, the carriers are bunched within the conducting wire, thus amplifying the current through the solid state Klystron at a frequency of the signal to the signal gate, thus achieving a power gain. | 07-19-2012 |
20120190155 | NANOWIRE MOSFET WITH DOPED EPITAXIAL CONTACTS FOR SOURCE AND DRAIN - A FET structure with a nanowire forming the FET channel, and doped source and drain regions formed by radial epitaxy from the nanowire body is disclosed. A top gated and a bottom gated nanowire FET structures are discussed. The source and drain fabrication can use either selective or non-selective epitaxy. | 07-26-2012 |
20120193678 | FABRICATION OF A VERTICAL HETEROJUNCTION TUNNEL-FET - Exemplary embodiments include a method for fabricating a heterojunction tunnel field-effect-transistor (FET), the method including forming a gate region on a silicon layer of a silicon-on-insulator (SOI) substrate, forming a drain region on the silicon layer adjacent the gate region and forming a vertical heterojunction source region adjacent the gate region, wherein the vertical heterojunction source region generates a tunnel path inline with a gate field associated with the gate region. | 08-02-2012 |
20120292677 | FERROELECTRIC SEMICONDUCTOR TRANSISTOR DEVICES HAVING GATE MODULATED CONDUCTIVE LAYER - Ferroelectric semiconductor switching devices are provided, including field effect transistor (FET) devices having gate stack structures formed with a ferroelectric layer disposed between a gate contact and a thin conductive layer (“quantum conductive layer”) . The gate contact and ferroelectric layer serve to modulate an effective work function of the thin conductive layer. The thin conductive layer with the modulated work function is coupled to a semiconductor channel layer to modulate current flow through the semiconductor and achieve a steep sub-threshold slope. | 11-22-2012 |
20120298965 | MULTIGATE STRUCTURE FORMED WITH ELECTROLESS METAL DEPOSITION - A multigate structure which comprises a semiconductor substrate; an ultra-thin silicon or carbon bodies of less than 20 nanometers thick located on the substrate; an electrolessly deposited metallic layer selectively located on the side surfaces and top surfaces of the ultra-thin silicon or carbon bodies and selectively located on top of the multigate structures to make electrical contact with the ultra-thin silicon or carbon bodies and to minimize parasitic resistance, and wherein the ultra-thin silicon or carbon bodies and metallic layer located thereon form source and drain regions is provided along with a process to fabricate the structure. | 11-29-2012 |
20120326605 | SOLID STATE KLYSTRON - A solid state Klystron structure is fabricated by forming a source contact and a drain contact to both ends of a conducting wire and by forming a bias gate and a signal gate on the conducting wire. The conducting wire may be at least one carbon nanotube or at least one semiconductor wire with long ballistic mean free paths. By applying a signal at a frequency that corresponds to an integer multiple of the transit time of the ballistic carriers between adjacent fingers of the signal gate, the carriers are bunched within the conducting wire, thus amplifying the current through the solid state Klystron at a frequency of the signal to the signal gate, thus achieving a power gain. | 12-27-2012 |
20130005105 | SOLID STATE KLYSTRON - A solid state Klystron structure is fabricated by forming a source contact and a drain contact to both ends of a conducting wire and by forming a bias gate and a signal gate on the conducting wire. The conducting wire may be at least one carbon nanotube or at least one semiconductor wire with long ballistic mean free paths. By applying a signal at a frequency that corresponds to an integer multiple of the transit time of the ballistic carriers between adjacent fingers of the signal gate, the carriers are bunched within the conducting wire, thus amplifying the current through the solid state Klystron at a frequency of the signal to the signal gate, thus achieving a power gain. | 01-03-2013 |
20130009668 | 4-TERMINAL PIEZOELECTRONIC TRANSISTOR (PET) - A 4-terminal piezoelectronic transistor (PET) which includes a piezoelectric (PE) material disposed between first and second electrodes; an insulator material disposed on the second electrode; a third electrode disposed on the insulator material and a piezoresistive (PR) material disposed between the third electrode and a fourth electrode. An applied voltage across the first and second electrodes causing a pressure from the PE material to be applied to the PR material through the insulator material, the electrical resistance of the PR material being dependent upon the pressure applied by the PE material. The first and second electrodes are electrically isolated from the third and fourth electrodes. Also disclosed are logic devices fabricated from 4-terminal PETs and a method of fabricating a 4-terminal PET. | 01-10-2013 |
20130241007 | USE OF BAND EDGE GATE METALS AS SOURCE DRAIN CONTACTS - A method includes providing a semiconductor substrate having intentionally doped surface regions, the intentionally doped surface regions corresponding to locations of a source and a drain of a transistor; depositing a layer a band edge gate metal onto a gate insulator layer in a gate region of the transistor while simultaneously depositing the band edge gate metal onto the surface of the semiconductor substrate to be in contact with the intentionally doped surface regions; and depositing a layer of contact metal over the band edge gate metal in the gate region and in the locations of the source and the drain. The band edge gate metal in the source/drain regions reduces a Schottky barrier height of source/drain contacts of the transistor and serves to reduce contact resistance. A transistor fabricated in accordance with the method is also described. | 09-19-2013 |
20130241008 | Use of Band Edge Gate Metals as Source Drain Contacts - A device includes a gate stack formed over a channel in a semiconductor substrate. The gate stack includes a layer of gate insulator material, a layer of gate metal overlying the layer of gate insulator material, and a layer of contact metal overlying the layer band edge gate metal. The device further includes source and drain contacts adjacent to the channel. The source and drain contacts each include a layer of the gate metal that overlies and is in direct electrical contact with a doped region of the semiconductor substrate, and a layer of contact metal that overlies the layer of gate metal. | 09-19-2013 |
20140042385 | CONTACTS-FIRST SELF-ALIGNED CARBON NANOTUBE TRANSISTOR WITH GATE-ALL-AROUND - A method of fabricating a semiconducting device is disclosed. A carbon nanotube is deposited on a substrate of the semiconducting device. A first contact on the substrate over the carbon nanotube. A second contact on the substrate over the carbon nanotube, wherein the second contact is separated from the first contact by a gap. A portion of the substrate in the gap between the first contact and the second contact is removed. | 02-13-2014 |
20140045303 | CONTACTS-FIRST SELF-ALIGNED CARBON NANOTUBE TRANSISTOR WITH GATE-ALL-AROUND - A method of fabricating a semiconducting device is disclosed. A carbon nanotube is deposited on a substrate of the semiconducting device. A first contact on the substrate over the carbon nanotube. A second contact on the substrate over the carbon nanotube, wherein the second contact is separated from the first contact by a gap. A portion of the substrate in the gap between the first contact and the second contact is removed. | 02-13-2014 |
20140169078 | PIEZOELECTRONIC MEMORY - A memory element includes a first piezotronic transistor coupled to a second piezotronic transistor; the first and second piezotronic transistors each comprising a piezoelectric (PE) material and a piezoresistive (PR) material, wherein an electrical resistance of the PR material is dependent upon an applied voltage across the PE material by way of an applied pressure to the PR material by the PE material. | 06-19-2014 |
20140306290 | Dual Silicide Process Compatible with Replacement-Metal-Gate - In one aspect, a method for fabricating an electronic device includes the following steps. A wafer is provided having at least one first active area and at least one second active area defined therein. One or more p-FET/n-FET devices are formed in the active areas, each having a p-FET/n-FET gate stack and p-FET/n-FET source and drain regions. A self-aligned silicide is formed in each of the p-FET/n-FET source and drain regions, wherein the self-aligned silicide in each of the p-FET source and drain regions has a thickness T1 and the self-aligned silicide in each of the n-FET source and drain regions having a thickness T2, wherein T1 is less than T2. During a subsequent trench silicidation in the p-FET/n-FET source and drain regions, the trench silicide metal will diffuse through the thinner self-aligned silicide in the p-FET device(s) but not through the thicker self-aligned silicide in the n-FET device(s). | 10-16-2014 |
20140306291 | Dual Silicide Process Compatible with Replacement-Metal-Gate - In one aspect, a method for fabricating an electronic device includes the following steps. A wafer is provided having at least one first active area and at least one second active area defined therein. One or more p-FET/n-FET devices are formed in the active areas, each having a p-FET/n-FET gate stack and p-FET/n-FET source and drain regions. A self-aligned silicide is formed in each of the p-FET/n-FET source and drain regions, wherein the self-aligned silicide in each of the p-FET source and drain regions has a thickness T1 and the self-aligned silicide in each of the n-FET source and drain regions having a thickness T2, wherein T1 is less than T2. During a subsequent trench silicidation in the p-FET/n-FET source and drain regions, the trench silicide metal will diffuse through the thinner self-aligned silicide in the p-FET device(s) but not through the thicker self-aligned silicide in the n-FET device(s). | 10-16-2014 |