Patent application number | Description | Published |
20080203381 | Forming arsenide-based complementary logic on a single substrate - In one embodiment, the present invention includes a method for forming a logic device, including forming an n-type semiconductor device over a silicon (Si) substrate that includes an indium gallium arsenide (InGaAs)-based stack including a first buffer layer, a second buffer layer formed over the first buffer layer, a first device layer formed over the second buffer layer. Further, the method may include forming a p-type semiconductor device over the Si substrate from the InGaAs-based stack and forming an isolation between the n-type semiconductor device and the p-type semiconductor device. Other embodiments are described and claimed. | 08-28-2008 |
20080237572 | FORMING A TYPE I HETEROSTRUCTURE IN A GROUP IV SEMICONDUCTOR - In one embodiment, the present invention includes a method for forming a transistor that includes forming a first buffer layer of silicon germanium tin (SiGe(Sn)) on a silicon (Si) substrate, forming a barrier layer on the first buffer layer, the barrier layer comprising silicon germanium (Si | 10-02-2008 |
20080237573 | Mechanism for forming a remote delta doping layer of a quantum well structure - A method of fabricating a quantum well device includes forming a diffusion barrier on sides of a delta layer of a quantum well to confine dopants to the quantum well. | 10-02-2008 |
20080237575 | Silicon germanium and germanium multigate and nanowire structures for logic and multilevel memory applications - A method to provide a transistor or memory cell structure. The method comprises: providing a substrate including a lower Si substrate and an insulating layer on the substrate; providing a first projection extending above the insulating layer, the first projection including an Si material and a Si1-xGex material; and exposing the first projection to preferential oxidation to yield a second projection including a center region comprising Ge/Si1-yGey and a covering region comprising SiO2 and enclosing the center region. | 10-02-2008 |
20080237636 | Transistor having tensile strained channel and system including same - A transistor structure and a system including the transistor structure. The transistor structure comprises: a substrate including a first layer comprising a first crystalline material; a tensile strained channel formed on a surface of the first layer and comprising a second crystalline material having a lattice spacing that is smaller than a lattice spacing of the first crystalline material; a metal gate on the substrate; a pair of sidewall spacers on opposite sides of the metal gate; and a source region and a drain region on opposite sides of the metal gate adjacent a corresponding one of the sidewall spacers. | 10-02-2008 |
20080237678 | On-chip memory cell and method of manufacturing same - An on-chip memory cell comprises a tri-gate access transistor ( | 10-02-2008 |
20080237719 | Multi-gate structure and method of doping same - A multi-gate structure includes a substrate ( | 10-02-2008 |
20080237735 | Hetero-Bimos injection process for non-volatile flash memory - A hetero-BiMOS injection system comprises a MOSFET transistor formed on a substrate and a hetero-bipolar transistor formed within the substrate. The bipolar transistor can be used to inject charge carriers into a floating gate of the MOSFET transistor. This is done by operating the MOSFET transistor to form an inversion layer in its channel region and operating the bipolar transistor to drive minority charge carriers from the substrate into a floating gate of the MOSFET transistor. The substrate provides a silicon emitter and a silicon germanium containing base for the bipolar transistor. The inversion layer provides a silicon collector for the bipolar transistor. | 10-02-2008 |
20080237751 | CMOS Structure and method of manufacturing same - A CMOS structure includes a substrate ( | 10-02-2008 |
20080318385 | Tunneling field effect transistor using angled implants for forming asymmetric source/drain regions - The present invention relates to a Tunnel Field Effect Transistor (TFET), which utilizes angle implantation and amorphization to form asymmetric source and drain regions. The TFET further comprises a silicon germanium alloy epitaxial source region with a conductivity opposite that of the drain. | 12-25-2008 |
20090001441 | Three dimensional quantum dot array - In one embodiment of the invention, oxidation of silicon in a silicon germanium/silicon lattice may convert a two dimensional array of silicon germanium pillars into a structured three dimensional quantum dot array. The array may be included in, for example, flash memory floating gate, optical detector, or quantum computing device. | 01-01-2009 |
20090001474 | Semiconductor device with reduced fringe capacitance - In one embodiment of the invention, a non-planar transistor includes a gate electrode and multiple fins. A trench contact is coupled to the fins. The contact bottom is formed above the substrate and does not directly contact the substrate. The contact bottom is higher than the gate top. | 01-01-2009 |
20090004868 | Amorphous silicon oxidation patterning - In one embodiment, a method comprises forming a sacrificial amorphous silicon layer on a semiconductor substrate, forming a hardmask on the amorphous silicon layer, etching one or more lines in the sacrificial amorphous silicon layer, growing oxide structures on the amorphous silicon layer, and forming a trench in the semiconductor substrate between the oxide structures. | 01-01-2009 |
20090039476 | Apparatus and method for selectively recessing spacers on multi-gate devices - Embodiments of an apparatus and methods for fabricating a spacer on one part of a multi-gate transistor without forming a spacer on another part of the multi-gate transistor are generally described herein. Other embodiments may be described and claimed. | 02-12-2009 |
20090057648 | High Hole Mobility P-Channel Ge Transistor Structure on Si Substrate - The present disclosure provides an apparatus and method for implementing a high hole mobility p-channel Germanium (“Ge”) transistor structure on a Silicon (“Si”) substrate. One exemplary apparatus may include a buffer layer including a GaAs nucleation layer, a first GaAs buffer layer, and a second GaAs buffer layer. The exemplary apparatus may further include a bottom barrier on the second GaAs buffer layer and having a band gap greater than 1.1 eV, a Ge active channel layer on the bottom barrier and having a valence band offset relative to the bottom barrier that is greater than 0.3 eV, and an AlAs top barrier on the Ge active channel layer wherein the AlAs top barrier has a band gap greater than 1.1 eV. Of course, many alternatives, variations and modifications are possible without departing from this embodiment. | 03-05-2009 |
20090061611 | FABRICATING DUAL LAYER GATE ELECTRODES HAVING POLYSILICON AND A WORKFUNCTION METAL - A method for fabricating a dual layer gate electrode having a polysilicon layer and a workfunction metal layer comprises depositing a layer of a workfunction metal on a semiconductor substrate, depositing a layer of polysilicon on the workfunction metal layer, depositing a hard mask layer on the polysilicon layer, etching the hard mask layer to form a hard mask structure defining a gate electrode, etching the polysilicon layer to remove a portion of the polysilicon layer not protected by the hard mask structure, thereby forming a polysilicon structure beneath the hard mask structure, applying a mixture of ozone and water to exposed sidewalls of the polysilicon structure, thereby forming a silicon dioxide layer on the sidewalls, and etching the workfunction metal layer to remove a portion of the workfunction metal layer not protected by the hard mask structure, thereby forming a workfunction metal structure beneath the polysilicon structure. | 03-05-2009 |
20090085027 | THREE DIMENSIONAL STRAINED QUANTUM WELLS AND THREE DIMENSIONAL STRAINED SURFACE CHANNELS BY GE CONFINEMENT METHOD - The present disclosure describes a method and apparatus for implementing a 3D (three dimensional) strained high mobility quantum well structure, and a 3D strained surface channel structure through a Ge confinement method. One exemplary apparatus may include a first graded SiGe fin on a Si substrate. The first graded SiGe fin may have a maximum Ge concentration greater than about 60%. A Ge quantum well may be on the first graded SiGe fin and a SiGe quantum well upper barrier layer may be on the Ge quantum well. The exemplary apparatus may further include a second graded SiGe fin on the Si substrate. The second graded SiGe fin may have a maximum Ge concentration less than about 40%. A Si active channel layer may be on the second graded SiGe fin. Other high mobility materials such as III-V semiconductors may be used as the active channel materials. Of course, many alternatives, variations and modifications are possible without departing from this embodiment. | 04-02-2009 |
20090090976 | PROCESS FOR INTEGRATING PLANAR AND NON-PLANAR CMOS TRANSISTORS ON A BULK SUBSTRATE AND ARTICLE MADE THEREBY - A process capable of integrating both planar and non-planar transistors onto a bulk semiconductor substrate, wherein the channel of all transistors is definable over a continuous range of widths. | 04-09-2009 |
20090095984 | DIELECTRIC INTERFACE FOR GROUP III-V SEMICONDUCTOR DEVICE - A Group III-V Semiconductor device and method of fabrication is described. A high-k dielectric is interfaced to a confinement region by a chalcogenide region. | 04-16-2009 |
20090127541 | REDUCING DEFECTS IN SEMICONDUCTOR QUANTUM WELL HETEROSTRUCTURES - Reducing defects in semiconductor quantum well structures is generally described. In one example, an apparatus includes a semiconductor substrate including silicon, a buffer film epitaxially grown on the semiconductor substrate, the buffer film comprising silicon, germanium, and an impurity, and a first semiconductor film epitaxially grown on the buffer film wherein a lattice mismatch exists between the semiconductor substrate and the first semiconductor film and wherein the impurity disrupts lattice structure dislocation gliding in at least the first semiconductor film. | 05-21-2009 |
20090140341 | INDEPENDENT N-TIPS FOR MULTI-GATE TRANSISTORS - Independent n-tips for multi-gate transistors are generally described. In one example, an apparatus includes a semiconductor fin, one or more multi-gate pull down (PD) devices coupled with the semiconductor fin, the one or more PD devices having an n-tip dopant concentration in the semiconductor fin material adjacent to the one or more PD devices, and one or more multi-gate pass gate (PG) devices coupled with the semiconductor fin, the one or more PG devices having an n-tip dopant concentration in the semiconductor fin material adjacent to the one or more PG devices, wherein the n-tip dopant concentration for the PG device is lower than the n-tip dopant concentration for the PD device. | 06-04-2009 |
20090166741 | REDUCING EXTERNAL RESISTANCE OF A MULTI-GATE DEVICE USING SPACER PROCESSING TECHNIQUES - Reducing external resistance of a multi-gate device using spacer processing techniques is generally described. In one example, a method includes depositing a sacrificial gate electrode to one or more multi-gate fins, the one or more multi-gate fins comprising a gate region, a source region, and a drain region, the gate region being disposed between the source and drain regions, patterning the sacrificial gate electrode such that the sacrificial gate electrode material is coupled to the gate region and substantially no sacrificial gate electrode is coupled to the source and drain regions of the one or more multi-gate fins, forming a dielectric film coupled to the source and drain regions of the one or more multi-gate fins, removing the sacrificial gate electrode from the gate region of the one or more multi-gate fins, depositing spacer gate dielectric to the gate region of the one or more multi-gate fins wherein substantially no spacer gate dielectric is deposited to the source and drain regions of the one or more multi-gate fins, the source and drain regions being protected by the dielectric film, and etching the spacer gate dielectric to completely remove the spacer gate dielectric from the gate region area to be coupled with a final gate electrode except a remaining pre-determined thickness of spacer gate dielectric to be coupled with the final gate electrode that remains coupled with the dielectric film. | 07-02-2009 |
20090166742 | REDUCING EXTERNAL RESISTANCE OF A MULTI-GATE DEVICE BY INCORPORATION OF A PARTIAL METALLIC FIN - Reducing external resistance of a multi-gate device by incorporation of a partial metallic fin is generally described. In one example, an apparatus includes a semiconductor substrate and one or more fins of a multi-gate transistor device coupled with the semiconductor substrate, the one or more fins having a gate region, a source region, and a drain region, the gate region being disposed between the source and drain regions where the gate region of the one or more fins includes a semiconductor material and where the source and drain regions of the one or more fins include a metal portion and a semiconductor portion, the metal portion and the semiconductor portion being coupled together. | 07-02-2009 |
20090166743 | INDEPENDENT GATE ELECTRODES TO INCREASE READ STABILITY IN MULTI-GATE TRANSISTORS - Independent gate electrodes for multi-gate transistors are generally described. In one example, an apparatus includes a semiconductor fin, one or more multi-gate pull down (PD) gate stacks coupled with the semiconductor fin, the one or more PD gate stacks including a PD gate electrode, and one or more multi-gate pass gate (PG) gate stacks coupled with the semiconductor fin, the one or more PG gate stacks including a PG gate electrode, the PG gate electrode having a greater threshold voltage than the PD gate electrode. | 07-02-2009 |
20090170251 | Fabrication of germanium nanowire transistors - In general, in one aspect, a method includes using the Germanium nanowire as building block for high performance logic, memory and low dimensional quantum effect devices. The Germanium nanowire channel and the SiGe anchoring regions are formed simultaneously through preferential Si oxidation of epitaxial Silicon Germanium epi layer. The placement of the germanium nanowires is accomplished using a Si fin as a template and the germanium nanowire is held on Si substrate through SiGe anchors created by masking the two ends of the fins. High dielectric constant gate oxide and work function metals wrap around the Germanium nanowire for gate-all-around electrostatic channel on/off control, while the Germanium nanowire provides high carrier mobility in the transistor channel region. The germanium nanowire transistors enable high performance, low voltage (low power consumption) operation of logic and memory devices. | 07-02-2009 |
20090170267 | Tri-gate patterning using dual layer gate stack - In general, in one aspect, a method includes forming an n-diffusion fin and a p-diffusion fin in a semiconductor substrate. A high dielectric constant layer is formed over the substrate. A first work function metal layer is created over the n-diffusion fin and a second work function metal layer, thicker than the first, is created over the n-diffusion fin. A silicon germanium layer is formed over the first and second work function metal layers. A ploysilicon layer is formed over the silicon germanium layer and is polished. The ploysilicon layer over the first work function metal layer is thicker than the ploysilicon layer over the second work function metal layer. A hard mask is patterned and used to etch the ploysilicon layer and the silicon germanium layer to create gate stacks. The etch rate of the silicon germanium layer is faster over the first work function metal layer. | 07-02-2009 |
20090206324 | DISLOCATION REMOVAL FROM A GROUP III-V FILM GROWN ON A SEMICONDUCTOR SUBSTRATE - Dislocation removal from a group III-V film grown on a semiconductor substrate is generally described. In one example, an apparatus includes a semiconductor substrate, a buffer film including a group III-V semiconductor material epitaxially coupled to the semiconductor substrate wherein the buffer film includes material melted by laser pulse irradiation and recrystallized to substantially remove dislocations or defects from the buffer film, and a first semiconductor film epitaxially grown on the buffer film wherein a lattice mismatch exists between the semiconductor substrate and the first semiconductor film. | 08-20-2009 |
20090206404 | REDUCING EXTERNAL RESISTANCE OF A MULTI-GATE DEVICE BY SILICIDATION - Reducing external resistance of a multi-gate device by silicidation is generally described. In one example, an apparatus includes a semiconductor substrate, a multi-gate fin coupled with the semiconductor substrate, the multi-gate fin having a first surface, a second surface, and a third surface, the multi-gate fin also having a gate region, a source region, and a drain region, the gate region being disposed between the source and drain regions wherein the source and drain regions of the multi-gate fin are fully or substantially silicized with a metal silicide, and a spacer dielectric material coupled to the first surface and the second surface wherein the spacer dielectric material substantially covers the first surface and the second surface in the source and drain regions. | 08-20-2009 |
20090206406 | MULTI-GATE DEVICE HAVING A T-SHAPED GATE STRUCTURE - A multi-gate device having a T-shaped gate structure is generally described. In one example, an apparatus includes a semiconductor substrate, at least one multi-gate fin coupled with the semiconductor substrate, the multi-gate fin having a gate region, a source region, and a drain region, the gate region being positioned between the source and drain regions, a gate dielectric coupled to the gate region of the multi-gate fin, a gate electrode coupled to the gate dielectric, the gate electrode having a first thickness and a second thickness, the second thickness being greater than the first thickness, a first spacer dielectric coupled to a portion of the gate electrode having the first thickness, and a second spacer dielectric coupled to the first spacer dielectric and coupled to the gate electrode where the second spacer dielectric is coupled to a portion of the gate electrode having the second thickness. | 08-20-2009 |
20090230480 | Epitaxial silicon germanium for reduced contact resistance in field-effect transistors - A method for selectively relieving channel stress for n-channel transistors with recessed, epitaxial SiGe source and drain regions is described. This increases the electron mobility for the n-channel transistors without affecting the strain in p-channel transistors. The SiGe provides lower resistance when a silicide is formed. | 09-17-2009 |
20090242872 | DOUBLE QUANTUM WELL STRUCTURES FOR TRANSISTORS - Double quantum well structures for transistors are generally described. In one example, an apparatus includes a semiconductor substrate, one or more buffer layers coupled to the semiconductor substrate, a first barrier layer coupled to the one or more buffer layers, a first quantum well channel coupled with the first barrier layer wherein the first quantum well channel includes a group III-V semiconductor material or a group II-VI semiconductor material, or combinations thereof, a second barrier layer coupled to the first quantum well channel, and a second quantum well channel coupled to the barrier layer wherein the second quantum well channel includes a group III-V semiconductor material or a group II-VI semiconductor material, or combinations thereof. | 10-01-2009 |
20090267161 | INCREASING BODY DOPANT UNIFORMITY IN MULTI-GATE TRANSISTOR DEVICES - Techniques and structures for increasing body dopant uniformity in multi-gate transistor devices are generally described. In one example, an electronic device includes a semiconductor substrate, a multi-gate fin coupled with the semiconductor substrate, the multi-gate fin comprising a source region, a drain region, and a gate region wherein the gate region is disposed between the source region and the drain region, the gate region being body-doped after a sacrificial gate structure is removed from the multi-gate fin and before a subsequent gate structure is formed, a dielectric material coupled with the source region and the drain region of the multi-gate fin, and the subsequent gate structure coupled to the gate region of the multi-gate fin. | 10-29-2009 |
20090283496 | DIRECTING CARBON NANOTUBE GROWTH - Embodiments of the invention include apparatuses and methods relating to directed carbon nanotube growth using a patterned layer. In some embodiments, the patterned layer includes an inhibitor material that directs the growth of carbon nanotubes. | 11-19-2009 |
20090298266 | DOPANT CONFINEMENT IN THE DELTA DOPED LAYER USING A DOPANT SEGREGRATION BARRIER IN QUANTUM WELL STRUCTURES - A device grade III-V quantum well structure and method of manufacture is described. Embodiments of the present invention enable III-V InSb quantum well device layers with defect densities below 1×10 | 12-03-2009 |
20090302350 | Tensile Strained NMOS Transistor Using Group III-N Source/Drain Regions - Enhancement mode transistors are described where a Group III-N compound is used in the source and drain regions to place tensile strain on the channel. The source and drain regions may be raised or embedded, and fabricated in conjunction with recessed or raised compression regions for p channel transistors. | 12-10-2009 |
20090315114 | STRESS IN TRIGATE DEVICES USING COMPLIMENTARY GATE FILL MATERIALS - Embodiments relate to an improved tri-gate device having gate metal fills, providing compressive or tensile stress upon at least a portion of the tri-gate transistor, thereby increasing the carrier mobility and operating frequency. Embodiments also contemplate method for use of the improved tri-gate device. | 12-24-2009 |
20100163847 | QUANTUM WELL MOSFET CHANNELS HAVING UNI-AXIAL STRAIN CAUSED BY METAL SOURCE/DRAINS, AND CONFORMAL REGROWTH SOURCE/DRAINS - Embodiments described include straining transistor quantum well (QW) channel regions with metal source/drains, and conformal regrowth source/drains to impart a uni-axial strain in a MOS channel region. Removed portions of a channel layer may be filled with a junction material having a lattice spacing different than that of the channel material to causes a uni-axial strain in the channel, in addition to a bi-axial strain caused in the channel layer by a top barrier layer and a bottom buffer layer of the quantum well. | 07-01-2010 |
20100163926 | MODULATION-DOPED MULTI-GATE DEVICES - Modulation-doped multi-gate devices are generally described. In one example, an apparatus includes a semiconductor substrate having a surface, one or more buffer films coupled to the surface of the semiconductor substrate, a first barrier film coupled to the one or more buffer films, a multi-gate fin coupled to the first barrier film, the multi-gate fin comprising a source region, a drain region, and a channel region of a multi-gate device wherein the channel region is disposed between the source region and the drain region, a spacer film coupled to the multi-gate fin, and a doped film coupled to the spacer film. | 07-01-2010 |
20100163945 | Embedded memory cell and method of manufacturing same - An embedded memory cell includes a semiconducting substrate ( | 07-01-2010 |
20100163970 | Trigate transistor having extended metal gate electrode - A trigate device having an extended metal gate electrode comprises a semiconductor body having a top surface and opposing sidewalls formed on a substrate, an isolation layer formed on the substrate and around the semiconductor body, wherein a portion of the semiconductor body remains exposed above the isolation layer, and a gate stack formed on the top surface and opposing sidewalls of the semiconductor body, wherein the gate stack extends a depth into the isolation layer, thereby causing a bottom surface of the gate stack to be below a top surface of the isolation layer. | 07-01-2010 |
20100193771 | QUANTUM WELL MOSFET CHANNELS HAVING UNI-AXIAL STRAIN CAUSED BY METAL SOURCE/DRAINS, AND CONFORMAL REGROWTH SOURCE/DRAINS - Embodiments described include straining transistor quantum well (QW) channel regions with metal source/drains, and conformal regrowth source/drains to impart a uni-axial strain in a MOS channel region. Removed portions of a channel layer may be filled with a junction material having a lattice spacing different than that of the channel material to causes a uni-axial strain in the channel, in addition to a bi-axial strain caused in the channel layer by a top barrier layer and a bottom buffer layer of the quantum well. | 08-05-2010 |
20100193840 | SUBSTRATE BAND GAP ENGINEERED MULTI-GATE PMOS DEVICES - A multi-gate transistor and a method of forming a multi-gate transistor, the multi-gate transistor including a fin having an upper portion and a lower portion. The upper portion having a first band gap and the lower portion having a second band gap with the first band gap and the second band gap designed to inhibit current flow from the upper portion to the lower portion. The multi-gate transistor further including a gate structure having sidewalls electrically coupled with said upper portion and said lower portion and a substrate positioned below the fin. | 08-05-2010 |
20100200835 | FABRICATION OF GERMANIUM NANOWIRE TRANSISTORS - In general, in one aspect, a method includes using the Germanium nanowire as building block for high performance logic, memory and low dimensional quantum effect devices. The Germanium nanowire channel and the SiGe anchoring regions are formed simultaneously through preferential Si oxidation of epitaxial Silicon Germanium epi layer. The placement of the germanium nanowires is accomplished using a Si fin as a template and the germanium nanowire is held on Si substrate through SiGe anchors created by masking the two ends of the fins. High dielectric constant gate oxide and work function metals wrap around the Germanium nanowire for gate-all-around electrostatic channel on/off control, while the Germanium nanowire provides high carrier mobility in the transistor channel region. The germanium nanowire transistors enable high performance, low voltage (low power consumption) operation of logic and memory devices. | 08-12-2010 |
20100219396 | Mechanism for Forming a Remote Delta Doping Layer of a Quantum Well Structure - A method of fabricating a quantum well device includes forming a diffusion barrier on sides of a delta layer of a quantum well to confine dopants to the quantum well. | 09-02-2010 |
20100248209 | Three-dimensional integrated circuit for analyte detection - The embodiments of the invention relate to a device having a first substrate comprising a transistor; a second substrate; an insulating layer in between and adjoining the first and second substrates; and an opening within the second substrate, the opening being aligned with the transistor; wherein the transistor is configured to detect an electrical charge change within the opening. Other embodiments relate to a method including providing a substrate comprising a first part, a second part, and an insulating layer in between and adjoining the first and second parts; fabricating a transistor on the first part; and fabricating an opening within the second part, the opening being aligned with the transistor; wherein the transistor is configured to detect an electrical charge change within the opening. | 09-30-2010 |
20100289062 | Carrier mobility in surface-channel transistors, apparatus made therewith, and systems containing same - A surface channel transistor is provided in a semiconductive device. The surface channel transistor is either a PMOS or an NMOS device. Epitaxial layers are disposed above the surface channel transistor to cause an increased bandgap phenomenon nearer the surface of the device. A process of forming the surface channel transistor includes grading the epitaxial layers. | 11-18-2010 |
20100327261 | HIGH HOLE MOBILITY P-CHANNEL GE TRANSISTOR STRUCTURE ON SI SUBSTRATE - The present disclosure provides an apparatus and method for implementing a high hole mobility p-channel Germanium (“Ge”) transistor structure on a Silicon (“Si”) substrate. One exemplary apparatus may include a buffer layer including a GaAs nucleation layer, a first GaAs buffer layer, and a second GaAs buffer layer. The exemplary apparatus may further include a bottom barrier on the second GaAs buffer layer and having a band gap greater than 1.1 eV, a Ge active channel layer on the bottom barrier and having a valence band offset relative to the bottom barrier that is greater than 0.3 eV, and an AlAs top barrier on the Ge active channel layer wherein the AlAs top barrier has a band gap greater than 1.1 eV. Of course, many alternatives, variations and modifications are possible without departing from this embodiment. | 12-30-2010 |
20100327377 | Fermi-level unpinning structures for semiconductive devices, processes of forming same, and systems containing same - An interlayer is used to reduce Fermi-level pinning phenomena in a semiconductive device with a semiconductive substrate. The interlayer may be a rare-earth oxide. The interlayer may be an ionic semiconductor. A metallic barrier film may be disposed between the interlayer and a metallic coupling. The interlayer may be a thermal-process combination of the metallic barrier film and the semiconductive substrate. A process of forming the interlayer may include grading the interlayer. A computing system includes the interlayer. | 12-30-2010 |
20110008937 | SILICON GERMANIUM AND GERMANIUM MULTIGATE AND NANOWIRE STRUCTURES FOR LOGIC AND MULTILEVEL MEMORY APPLICATIONS - A method to provide a transistor or memory cell structure. The method comprises: providing a substrate including a lower Si substrate and an insulating layer on the substrate; providing a first projection extending above the insulating layer, the first projection including an Si material and a Si1-xGex material; and exposing the first projection to preferential oxidation to yield a second projection including a center region comprising Ge/Si1-yGey and a covering region comprising SiO2 and enclosing the center region. | 01-13-2011 |
20110017978 | STRAIN-INDUCING SEMICONDUCTOR REGIONS - A method to form a strain-inducing semiconductor region is described. In one embodiment, formation of a strain-inducing semiconductor region laterally adjacent to a crystalline substrate results in a uniaxial strain imparted to the crystalline substrate, providing a strained crystalline substrate. In another embodiment, a semiconductor region with a crystalline lattice of one or more species of charge-neutral lattice-forming atoms imparts a strain to a crystalline substrate, wherein the lattice constant of the semiconductor region is different from that of the crystalline substrate, and wherein all species of charge-neutral lattice-forming atoms of the semiconductor region are contained in the crystalline substrate. | 01-27-2011 |
20110062520 | METHOD FOR FABRICATING TRANSISTOR WITH THINNED CHANNEL - A method of fabricating a MOS transistor having a thinned channel region is described. The channel region is etched following removal of a dummy gate. The source and drain regions have relatively low resistance with the process. | 03-17-2011 |
20110121266 | QUANTUM WELL MOSFET CHANNELS HAVING UNI-AXIAL STRAIN CAUSED BY METAL SOURCE/DRAINS, AND CONFORMAL REGROWTH SOURCE/DRAINS - Embodiments described include straining transistor quantum well (QW) channel regions with metal source/drains, and conformal regrowth source/drains to impart a uni-axial strain in a MOS channel region. Removed portions of a channel layer may be filled with a junction material having a lattice spacing different than that of the channel material to causes a uni-axial strain in the channel, in addition to a bi-axial strain caused in the channel layer by a top barrier layer and a bottom buffer layer of the quantum well. | 05-26-2011 |
20110147711 | NON-PLANAR GERMANIUM QUANTUM WELL DEVICES - Techniques are disclosed for forming a non-planar germanium quantum well structure. In particular, the quantum well structure can be implemented with group IV or III-V semiconductor materials and includes a germanium fin structure. In one example case, a non-planar quantum well device is provided, which includes a quantum well structure having a substrate (e.g. SiGe or GaAs buffer on silicon), a IV or III-V material barrier layer (e.g., SiGe or GaAs or AlGaAs), a doping layer (e.g., delta/modulation doped), and an undoped germanium quantum well layer. An undoped germanium fin structure is formed in the quantum well structure, and a top barrier layer deposited over the fin structure. A gate metal can be deposited across the fin structure. Drain/source regions can be formed at respective ends of the fin structure. | 06-23-2011 |
20110147713 | TECHNIQUES FOR FORMING CONTACTS TO QUANTUM WELL TRANSISTORS - Techniques are disclosed for providing a low resistance self-aligned contacts to devices formed in a semiconductor heterostructure. The techniques can be used, for example, for forming contacts to the gate, source and drain regions of a quantum well transistor fabricated in III-V and SiGe/Ge material systems. Unlike conventional contact process flows which result in a relatively large space between the source/drain contacts to gate, the resulting source and drain contacts provided by the techniques described herein are self-aligned, in that each contact is aligned to the gate electrode and isolated therefrom via spacer material. | 06-23-2011 |
20110147798 | CONDUCTIVITY IMPROVEMENTS FOR III-V SEMICONDUCTOR DEVICES - Conductivity improvements in III-V semiconductor devices are described. A first improvement includes a barrier layer that is not coextensively planar with a channel layer. A second improvement includes an anneal of a metal/Si, Ge or SiliconGermanium/III-V stack to form a metal-Silicon, metal-Germanium or metal-SiliconGermanium layer over a Si and/or Germanium doped III-V layer. Then, removing the metal layer and forming a source/drain electrode on the metal-Silicon, metal-Germanium or metal-SiliconGermanium layer. A third improvement includes forming a layer of a Group IV and/or Group VI element over a III-V channel layer, and, annealing to dope the III-V channel layer with Group IV and/or Group VI species. A fourth improvement includes a passivation and/or dipole layer formed over an access region of a III-V device. | 06-23-2011 |
20110147811 | TWO-DIMENSIONAL CONDENSATION FOR UNIAXIALLY STRAINED SEMICONDUCTOR FINS - Techniques are disclosed for enabling multi-sided condensation of semiconductor fins. The techniques can be employed, for instance, in fabricating fin-based transistors. In one example case, a strain layer is provided on a bulk substrate. The strain layer is associated with a critical thickness that is dependent on a component of the strain layer, and the strain layer has a thickness lower than or equal to the critical thickness. A fin is formed in the substrate and strain layer, such that the fin includes a substrate portion and a strain layer portion. The fin is oxidized to condense the strain layer portion of the fin, so that a concentration of the component in the strain layer changes from a pre-condensation concentration to a higher post-condensation concentration, thereby causing the critical thickness to be exceeded. | 06-23-2011 |
20110147847 | Methods and apparatus to reduce layout based strain variations in non-planar transistor structures - The present disclosure relates to the field of fabricating microelectronic devices. In at least one embodiment, the present disclosure relates to forming isolation structures in strained semiconductor bodies of non-planar transistors while maintaining strain in the semiconductor bodies. | 06-23-2011 |
20110156005 | Germanium-based quantum well devices - A quantum well transistor has a germanium quantum well channel region. A silicon-containing etch stop layer provides easy placement of a gate dielectric close to the channel. A group III-V barrier layer adds strain to the channel. Graded silicon germanium layers above and below the channel region improve performance. Multiple gate dielectric materials allow use of a high-k value gate dielectric. | 06-30-2011 |
20110156006 | Forming A Non-Planar Transistor Having A Quantum Well Channel - In one embodiment, the present invention includes an apparatus having a substrate, a buried oxide layer formed on the substrate, a silicon on insulator (SOI) core formed on the buried oxide layer, a compressive strained quantum well (QW) layer wrapped around the SOI core, and a tensile strained silicon layer wrapped around the QW layer. Other embodiments are described and claimed. | 06-30-2011 |
20110180851 | CMOS DEVICES WITH A SINGLE WORK FUNCTION GATE ELECTRODE AND METHOD OF FABRICATION - Described herein are a device utilizing a gate electrode material with a single work function for both the pMOS and nMOS transistors where the magnitude of the transistor threshold voltages is modified by semiconductor band engineering and article made thereby. Further described herein are methods of fabricating a device formed of complementary (pMOS and nMOS) transistors having semiconductor channel regions which have been band gap engineered to achieve a low threshold voltage. | 07-28-2011 |
20110284965 | REDUCING EXTERNAL RESISTANCE OF A MULTI-GATE DEVICE USING SPACER PROCESSING TECHNIQUES - Reducing external resistance of a multi-gate device using spacer processing techniques is generally described. In one example, a method includes depositing a sacrificial gate electrode to one or more multi-gate fins, the one or more multi-gate fins comprising a gate region, a source region, and a drain region, the gate region being disposed between the source and drain regions, patterning the sacrificial gate electrode such that the sacrificial gate electrode material is coupled to the gate region and substantially no sacrificial gate electrode is coupled to the source and drain regions of the one or more multi-gate fins, forming a dielectric film coupled to the source and drain regions of the one or more multi-gate fins, removing the sacrificial gate electrode from the gate region of the one or more to multi-gate fins, depositing spacer gate dielectric to the gate region of the one or more multi-gate fins wherein substantially no spacer gate dielectric is deposited to the source and drain regions of the one or more multi-gate fins, the source and drain regions being protected by the dielectric film, and etching the spacer gate dielectric to completely remove the spacer gate dielectric from the gate region area to be coupled with a final gate electrode except a remaining pre-determined thickness of spacer gate dielectric to be coupled with the final gate electrode that remains coupled with the dielectric film. | 11-24-2011 |
20110291192 | INCREASING BODY DOPANT UNIFORMITY IN MULTI-GATE TRANSISTOR DEVICES - Techniques and structures for increasing body dopant uniformity in multi-gate transistor devices are generally described. In one example, an electronic device includes a semiconductor substrate, a multi-gate fin coupled with the semiconductor substrate, the multi-gate fin comprising a source region, a drain region, and a gate region wherein the gate region is disposed between the source region and the drain region, the gate region being body-doped after a sacrificial gate structure is removed from the multi-gate fin and before a subsequent gate structure is formed, a dielectric material coupled with the source region and the drain region of the multi-gate fin, and the subsequent gate structure coupled to the gate region of the multi-gate fin. | 12-01-2011 |
20120018781 | MODULATION-DOPED MULTI-GATE DEVICES - Modulation-doped multi-gate devices are generally described. In one example, an apparatus includes a semiconductor substrate having a surface, one or more buffer films coupled to the surface of the semiconductor substrate, a first barrier film coupled to the one or more buffer films, a multi-gate fin coupled to the first barrier film, the multi-gate fin comprising a source region, a drain region, and a channel region of a multi-gate device wherein the channel region is disposed between the source region and the drain region, a spacer film coupled to the multi-gate fin, and a doped film coupled to the spacer film. | 01-26-2012 |
20120061649 | STRAIN-INDUCING SEMICONDUCTOR REGIONS - A method to form a strain-inducing semiconductor region is described. In one embodiment, formation of a strain-inducing semiconductor region laterally adjacent to a crystalline substrate results in a uniaxial strain imparted to the crystalline substrate, providing a strained crystalline substrate. In another embodiment, a semiconductor region with a crystalline lattice of one or more species of charge-neutral lattice-forming atoms imparts a strain to a crystalline substrate, wherein the lattice constant of the semiconductor region is different from that of the crystalline substrate, and wherein all species of charge-neutral lattice-forming atoms of the semiconductor region are contained in the crystalline substrate. | 03-15-2012 |
20120074464 | Non-planar device having uniaxially strained semiconductor body and method of making same - A method and a device made according to the method. The method comprises providing a substrate including a first material, and providing a fin including a second material, the fin being disposed on the substrate and having a device active portion, the first material and the second material presenting a lattice mismatch between respective crystalline structures thereof. Providing the fin includes providing a biaxially strained film including the second material on the substrate; and removing parts of the biaxially strained film to form a substantially uniaxially strained fin therefrom. | 03-29-2012 |
20120153387 | TRANSISTORS WITH HIGH CONCENTRATION OF BORON DOPED GERMANIUM - Techniques are disclosed for forming transistor devices having source and drain regions with high concentrations of boron doped germanium. In some embodiments, an in situ boron doped germanium, or alternatively, boron doped silicon germanium capped with a heavily boron doped germanium layer, are provided using selective epitaxial deposition in the source and drain regions and their corresponding tip regions. In some such cases, germanium concentration can be, for example, in excess of 50 atomic % and up to 100 atomic %, and the boron concentration can be, for instance, in excess of 1E20 cm | 06-21-2012 |
20120193609 | GERMANIUM-BASED QUANTUM WELL DEVICES - A quantum well transistor has a germanium quantum well channel region. A silicon-containing etch stop layer provides easy placement of a gate dielectric close to the channel. A group III-V barrier layer adds strain to the channel. Graded silicon germanium layers above and below the channel region improve performance. Multiple gate dielectric materials allow use of a high-k value gate dielectric. | 08-02-2012 |
20120199813 | EXTREME HIGH MOBILITY CMOS LOGIC - A CMOS device includes a PMOS transistor with a first quantum well structure and an NMOS device with a second quantum well structure. The PMOS and NMOS transistors are formed on a substrate. | 08-09-2012 |
20120211726 | Forming A Non-Planar Transistor Having A Quantum Well Channel - In one embodiment, the present invention includes an apparatus having a substrate, a buried oxide layer formed on the substrate, a silicon on insulator (SOI) core formed on the buried oxide layer, a compressive strained quantum well (QW) layer wrapped around the SOI core, and a tensile strained silicon layer wrapped around the QW layer. Other embodiments are described and claimed. | 08-23-2012 |
20120231596 | QUANTUM WELL MOSFET CHANNELS HAVING UNI-AXIAL STRAIN CAUSED BY METAL SOURCE/DRAINS, AND CONFORMAL REGROWTH SOURCE/DRAINS - Embodiments described include straining transistor quantum well (QW) channel regions with metal source/drains, and conformal regrowth source/drains to impart a uni-axial strain in a MOS channel region. Removed portions of a channel layer may be filled with a junction material having a lattice spacing different than that of the channel material to causes a uni-axial strain in the channel, in addition to a bi-axial strain caused in the channel layer by a top barrier layer and a bottom buffer layer of the quantum well. | 09-13-2012 |
20120241818 | TWO-DIMENSIONAL CONDENSATION FOR UNIAXIALLY STRAINED SEMICONDUCTOR FINS - Techniques are disclosed for enabling multi-sided condensation of semiconductor fins. The techniques can be employed, for instance, in fabricating fin-based transistors. In one example case, a strain layer is provided on a bulk substrate. The strain layer is associated with a critical thickness that is dependent on a component of the strain layer, and the strain layer has a thickness lower than or equal to the critical thickness. A fin is formed in the substrate and strain layer, such that the fin includes a substrate portion and a strain layer portion. The fin is oxidized to condense the strain layer portion of the fin, so that a concentration of the component in the strain layer changes from a pre-condensation concentration to a higher post-condensation concentration, thereby causing the critical thickness to be exceeded. | 09-27-2012 |
20120305990 | METHODS AND APPARATUS TO REDUCE LAYOUT BASED STRAIN VARIATIONS IN NON-PLANAR TRANSISTOR STRUCTURES - The present disclosure relates to the field of fabricating microelectronic devices. In at least one embodiment, the present disclosure relates to forming isolation structures in strained semiconductor bodies of non-planar transistors while maintaining strain in the semiconductor bodies. | 12-06-2012 |
20130032783 | NON-PLANAR GERMANIUM QUANTUM WELL DEVICES - Techniques are disclosed for forming a non-planar germanium quantum well structure. In particular, the quantum well structure can be implemented with group IV or III-V semiconductor materials and includes a germanium fin structure. In one example case, a non-planar quantum well device is provided, which includes a quantum well structure having a substrate (e.g. SiGe or GaAs buffer on silicon), a IV or III-V material barrier layer (e.g., SiGe or GaAs or AlGaAs), a doping layer (e.g., delta/modulation doped), and an undoped germanium quantum well layer. An undoped germanium fin structure is formed in the quantum well structure, and a top barrier layer deposited over the fin structure. A gate metal can be deposited across the fin structure. Drain/source regions can be formed at respective ends of the fin structure. | 02-07-2013 |
20130143385 | STRESS IN TRIGATE DEVICES USING COMPLIMENTARY GATE FILL MATERIALS - Embodiments relate to an improved tri-gate device having gate metal fills, providing compressive or tensile stress upon at least a portion of the tri-gate transistor, thereby increasing the carrier mobility and operating frequency. Embodiments also contemplate method for use of the improved tri-gate device. | 06-06-2013 |
20130146845 | TECHNIQUES FOR FORMING CONTACTS TO QUANTUM WELL TRANSISTORS - Techniques are disclosed for providing a low resistance self-aligned contacts to devices formed in a semiconductor heterostructure. The techniques can be used, for example, for forming contacts to the gate, source and drain regions of a quantum well transistor fabricated in III-V and SiGe/Ge material systems. Unlike conventional contact process flows which result in a relatively large space between the source/drain contacts to gate, the resulting source and drain contacts provided by the techniques described herein are self-aligned, in that each contact is aligned to the gate electrode and isolated therefrom via spacer material. | 06-13-2013 |
20130234113 | QUANTUM WELL MOSFET CHANNELS HAVING LATTICE MISMATCH WITH METAL SOURCE/DRAINS, AND CONFORMAL REGROWTH SOURCE/DRAINS - Embodiments described include straining transistor quantum well (QW) channel regions with metal source/drains, and conformal regrowth source/drains to impart a uni-axial strain in a MOS channel region. Removed portions of a channel layer may be filled with a junction material having a lattice spacing different than that of the channel material to causes a uni-axial strain in the channel, in addition to a bi-axial strain caused in the channel layer by a top barrier layer and a bottom buffer layer of the quantum well. | 09-12-2013 |
20130277714 | STRAIN COMPENSATION IN TRANSISTORS - Transistor structures having channel regions comprising alternating layers of compressively and tensilely strained epitaxial materials are provided. The alternating epitaxial layers can form channel regions in single and multigate transistor structures. In alternate embodiments, one of the two alternating layers is selectively etched away to form nanoribbons or nanowires of the remaining material. The resulting strained nanoribbons or nanowires form the channel regions of transistor structures. Also provided are computing devices comprising transistors comprising channel regions comprised of alternating compressively and tensilely strained epitaxial layers and computing devices comprising transistors comprising channel regions comprised of strained nanoribbons or nanowires. | 10-24-2013 |
20130292698 | III-N MATERIAL STRUCTURE FOR GATE-RECESSED TRANSISTORS - III-N transistors with recessed gates. An epitaxial stack includes a doped III-N source/drain layer and a III-N etch stop layer disposed between a the source/drain layer and a III-N channel layer. An etch process, e.g., utilizing photochemical oxidation, selectively etches the source/drain layer over the etch stop layer. A gate electrode is disposed over the etch stop layer to form a recessed-gate III-N HEMT. At least a portion of the etch stop layer may be oxidized with a gate electrode over the oxidized etch stop layer for a recessed gate III-N MOS-HEMT including a III-N oxide. A high-k dielectric may be formed over the oxidized etch stop layer with a gate electrode over the high-k dielectric to form a recessed gate III-N MOS-HEMT having a composite gate dielectric stack. | 11-07-2013 |
20130320455 | SEMICONDUCTOR DEVICE WITH ISOLATED BODY PORTION - Semiconductor devices with isolated body portions are described. For example, a semiconductor structure includes a semiconductor body disposed above a semiconductor substrate. The semiconductor body includes a channel region and a pair of source and drain regions on either side of the channel region. An isolation pedestal is disposed between the semiconductor body and the semiconductor substrate. A gate electrode stack at least partially surrounds a portion of the channel region of the semiconductor body. | 12-05-2013 |
20130328015 | EXTREME HIGH MOBILITY CMOS LOGIC - A CMOS device includes a PMOS transistor with a first quantum well structure and an NMOS device with a second quantum well structure. The PMOS and NMOS transistors are formed on a substrate. | 12-12-2013 |
20130341704 | VARIABLE GATE WIDTH FOR GATE ALL-AROUND TRANSISTORS - Nanowire-based gate all-around transistor devices having one or more active nanowires and one or more inactive nanowires are described herein. Methods to fabricate such devices are also described. One or more embodiments of the present invention are directed at approaches for varying the gate width of a transistor structure comprising a nanowire stack having a distinct number of nanowires. The approaches include rendering a certain number of nanowires inactive (i.e. so that current does not flow through the nanowire), by severing the channel region, burying the source and drain regions, or both. Overall, the gate width of nanowire-based structures having a plurality of nanowires may be varied by rendering a certain number of nanowires inactive, while maintaining other nanowires as active. | 12-26-2013 |
20130344668 | STRAIN-INDUCING SEMICONDUCTOR REGIONS - A method to form a strain-inducing semiconductor region is described. In one embodiment, formation of a strain-inducing semiconductor region laterally adjacent to a crystalline substrate results in a uniaxial strain imparted to the crystalline substrate, providing a strained crystalline substrate. In another embodiment, a semiconductor region with a crystalline lattice of one or more species of charge-neutral lattice-forming atoms imparts a strain to a crystalline substrate, wherein the lattice constant of the semiconductor region is different from that of the crystalline substrate, and wherein all species of charge-neutral lattice-forming atoms of the semiconductor region are contained in the crystalline substrate. | 12-26-2013 |
20140027816 | HIGH MOBILITY STRAINED CHANNELS FOR FIN-BASED TRANSISTORS - Techniques are disclosed for incorporating high mobility strained channels into fin-based transistors (e.g., FinFETs such as double-gate, trigate, etc), wherein a stress material is cladded onto the channel area of the fin. In one example embodiment, silicon germanium (SiGe) is cladded onto silicon fins to provide a desired stress, although other fin and cladding materials can be used. The techniques are compatible with typical process flows, and the cladding deposition can occur at a plurality of locations within the process flow. In some cases, the built-in stress from the cladding layer may be enhanced with a source/drain stressor that compresses both the fin and cladding layers in the channel. In some cases, an optional capping layer can be provided to improve the gate dielectric/semiconductor interface. In one such embodiment, silicon is provided over a SiGe cladding layer to improve the gate dielectric/semiconductor interface. | 01-30-2014 |
20140035041 | TECHNIQUES AND CONFIGURATIONS FOR STACKING TRANSISTORS OF AN INTEGRATED CIRCUIT DEVICE - Embodiments of the present disclosure provide techniques and configurations for stacking transistors of a memory device. In one embodiment, an apparatus includes a semiconductor substrate, a plurality of fin structures formed on the semiconductor substrate, wherein an individual fin structure of the plurality of fin structures includes a first isolation layer disposed on the semiconductor substrate, a first channel layer disposed on the first isolation layer, a second isolation layer disposed on the first channel layer, and a second channel layer disposed on the second isolation layer, and a gate terminal capacitively coupled with the first channel layer to control flow of electrical current through the first channel layer for a first transistor and capacitively coupled with the second channel layer to control flow of electrical current through the second channel layer for a second transistor. Other embodiments may be described and/or claimed. | 02-06-2014 |
20140054548 | TECHNIQUES FOR FORMING NON-PLANAR GERMANIUM QUANTUM WELL DEVICES - Techniques are disclosed for forming a non-planar germanium quantum well structure. In particular, the quantum well structure can be implemented with group IV or III-V semiconductor materials and includes a germanium fin structure. In one example case, a non-planar quantum well device is provided, which includes a quantum well structure having a substrate (e.g. SiGe or GaAs buffer on silicon), a IV or III-V material barrier layer (e.g., SiGe or GaAs or AlGaAs), a doping layer (e.g., delta/modulation doped), and an undoped germanium quantum well layer. An undoped germanium fin structure is formed in the quantum well structure, and a top barrier layer deposited over the fin structure. A gate metal can be deposited across the fin structure. Drain/source regions can be formed at respective ends of the fin structure. | 02-27-2014 |
20140061589 | GERMANIUM-BASED QUANTUM WELL DEVICES - A quantum well transistor has a germanium quantum well channel region. A silicon-containing etch stop layer provides easy placement of a gate dielectric close to the channel. A group III-V barrier layer adds strain to the channel. Graded silicon germanium layers above and below the channel region improve performance. Multiple gate dielectric materials allow use of a high-k value gate dielectric. | 03-06-2014 |
20140070273 | Non-Planar Device Having Uniaxially Strained Semiconductor Body and Method of Making Same - A method and a device made according to the method. The method comprises providing a substrate including a first material, and providing a fin including a second material, the fin being disposed on the substrate and having a device active portion, the first material and the second material presenting a lattice mismatch between respective crystalline structures thereof. Providing the fin includes providing a biaxially strained film including the second material on the substrate; and removing parts of the biaxially strained film to form a substantially uniaxially strained fin therefrom. | 03-13-2014 |
20140091360 | TRENCH CONFINED EPITAXIALLY GROWN DEVICE LAYER(S) - Trench-confined selective epitaxial growth process in which epitaxial growth of a semiconductor device layer proceeds within the confines of a trench. In embodiments, a trench is fabricated to include a pristine, planar semiconductor seeding surface disposed at the bottom of the trench. Semiconductor regions around the seeding surface may be recessed relative to the seeding surface with Isolation dielectric disposed there on to surround the semiconductor seeding layer and form the trench. In embodiments to form the trench, a sacrificial hardmask fin may be covered in dielectric which is then planarized to expose the hardmask fin, which is then removed to expose the seeding surface. A semiconductor device layer is formed from the seeding surface through selective heteroepitaxy. In embodiments, non-planar devices are formed from the semiconductor device layer by recessing a top surface of the isolation dielectric. In embodiments, non-planar devices CMOS devices having high carrier mobility may be made from the semiconductor device layer. | 04-03-2014 |
20140091361 | METHODS OF CONTAINING DEFECTS FOR NON-SILICON DEVICE ENGINEERING - An apparatus including a device including a channel material having a first lattice structure on a well of a well material having a matched lattice structure in a buffer material having a second lattice structure that is different than the first lattice structure. A method including forming a trench in a buffer material; forming an n-type well material in the trench, the n-type well material having a lattice structure that is different than a lattice structure of the buffer material; and forming an n-type transistor. A system including a computer including a processor including complimentary metal oxide semiconductor circuitry including an n-type transistor including a channel material, the channel material having a first lattice structure on a well disposed in a buffer material having a second lattice structure that is different than the first lattice structure, the n-type transistor coupled to a p-type transistor. | 04-03-2014 |
20140103396 | STRAIN-INDUCING SEMICONDUCTOR REGIONS - A method to form a strain-inducing semiconductor region is described. In one embodiment, formation of a strain-inducing semiconductor region laterally adjacent to a crystalline substrate results in a uniaxial strain imparted to the crystalline substrate, providing a strained crystalline substrate. In another embodiment, a semiconductor region with a crystalline lattice of one or more species of charge-neutral lattice-forming atoms imparts a strain to a crystalline substrate, wherein the lattice constant of the semiconductor region is different from that of the crystalline substrate, and wherein all species of charge-neutral lattice-forming atoms of the semiconductor region are contained in the crystalline substrate. | 04-17-2014 |
20140103397 | TECHNIQUES FOR FORMING NON-PLANAR GERMANIUM QUANTUM WELL DEVICES - Techniques are disclosed for forming a non-planar germanium quantum well structure. In particular, the quantum well structure can be implemented with group IV or III-V semiconductor materials and includes a germanium fin structure. In one example case, a non-planar quantum well device is provided, which includes a quantum well structure having a substrate (e.g. SiGe or GaAs buffer on silicon), a IV or III-V material barrier layer (e.g., SiGe or GaAs or AlGaAs), a doping layer (e.g., delta/modulation doped), and an undoped germanium quantum well layer. An undoped germanium fin structure is formed in the quantum well structure, and a top barrier layer deposited over the fin structure. A gate metal can be deposited across the fin structure. Drain/source regions can be formed at respective ends of the fin structure. | 04-17-2014 |
20140170817 | SILICON GERMANIUM AND GERMANIUM MULTIGATE AND NANOWIRE STRUCTURES FOR LOGIC AND MULTILEVEL MEMORY APPLICATIONS - A method to provide a transistor or memory cell structure. The method comprises: providing a substrate including a lower Si substrate and an insulating layer on the substrate; providing a first projection extending above the insulating layer, the first projection including an Si material and a Sil-xGex material; and exposing the first projection to preferential oxidation to yield a second projection including a center region comprising Ge/Sil-yGey and a covering region comprising SiO2 and enclosing the center region. | 06-19-2014 |
20140203327 | DEEP GATE-ALL-AROUND SEMICONDUCTOR DEVICE HAVING GERMANIUM OR GROUP III-V ACTIVE LAYER - Deep gate-all-around semiconductor devices having germanium or group III-V active layers are described. For example, a non-planar semiconductor device includes a hetero-structure disposed above a substrate. The hetero-structure includes a hetero-junction between an upper layer and a lower layer of differing composition. An active layer is disposed above the hetero-structure and has a composition different from the upper and lower layers of the hetero-structure. A gate electrode stack is disposed on and completely surrounds a channel region of the active layer, and is disposed in a trench in the upper layer and at least partially in the lower layer of the hetero-structure. Source and drain regions are disposed in the active layer and in the upper layer, but not in the lower layer, on either side of the gate electrode stack. | 07-24-2014 |
20140231871 | METHODS OF CONTAINING DEFECTS FOR NON-SILICON DEVICE ENGINEERING - An apparatus including a device including a channel material having a first lattice structure on a well of a well material having a matched lattice structure in a buffer material having a second lattice structure that is different than the first lattice structure. A method including forming a trench in a buffer material; forming an n-type well material in the trench, the n-type well material having a lattice structure that is different than a lattice structure of the buffer material; and forming an n-type transistor. A system including a computer including a processor including complimentary metal oxide semiconductor circuitry including an n-type transistor including a channel material, the channel material having a first lattice structure on a well disposed in a buffer material having a second lattice structure that is different than the first lattice structure, the n-type transistor coupled to a p-type transistor. | 08-21-2014 |
20140239400 | STRESS IN TRIGATE DEVICES USING COMPLIMENTARY GATE FILL MATERIALS - Embodiments relate to an improved tri-gate device having gate metal fills, providing compressive or tensile stress upon at least a portion of the tri-gate transistor, thereby increasing the carrier mobility and operating frequency. Embodiments also contemplate method for use of the improved tri-gate device. | 08-28-2014 |
20140291615 | EXTREME HIGH MOBILITY CMOS LOGIC - A CMOS device includes a PMOS transistor with a first quantum well structure and an NMOS device with a second quantum well structure. The PMOS and NMOS transistors are formed on a substrate. | 10-02-2014 |
20140291726 | TRENCH CONFINED EPITAXIALLY GROWN DEVICE LAYER(S) - Trench-confined selective epitaxial growth process in which epitaxial growth of a semiconductor device layer proceeds within the confines of a trench. In embodiments, a trench is fabricated to include a pristine, planar semiconductor seeding surface disposed at the bottom of the trench. Semiconductor regions around the seeding surface may be recessed relative to the seeding surface with Isolation dielectric disposed there on to surround the semiconductor seeding layer and form the trench. In embodiments to form the trench, a sacrificial hardmask fin may be covered in dielectric which is then planarized to expose the hardmask fin, which is then removed to expose the seeding surface. A semiconductor device layer is formed from the seeding surface through selective heteroepitaxy. In embodiments, non-planar devices are formed from the semiconductor device layer by recessing a top surface of the isolation dielectric. In embodiments, non-planar devices CMOS devices having high carrier mobility may be made from the semiconductor device layer. | 10-02-2014 |
20140326953 | TECHNIQUES FOR FORMING CONTACTS TO QUANTUM WELL TRANSISTORS - Techniques are disclosed for providing a low resistance self-aligned contacts to devices formed in a semiconductor heterostructure. The techniques can be used, for example, for forming contacts to the gate, source and drain regions of a quantum well transistor fabricated in III-V and SiGe/Ge material systems. Unlike conventional contact process flows which result in a relatively large space between the source/drain contacts to gate, the resulting source and drain contacts provided by the techniques described herein are self-aligned, in that each contact is aligned to the gate electrode and isolated therefrom via spacer material. | 11-06-2014 |
20150060945 | TRANSISTORS WITH HIGH CONCENTRATION OF BORON DOPED GERMANIUM - Techniques are disclosed for forming transistor devices having source and drain regions with high concentrations of boron doped germanium. In some embodiments, an in situ boron doped germanium, or alternatively, boron doped silicon germanium capped with a heavily boron doped germanium layer, are provided using selective epitaxial deposition in the source and drain regions and their corresponding tip regions. In some such cases, germanium concentration can be, for example, in excess of 50 atomic % and up to 100 atomic %, and the boron concentration can be, for instance, in excess of 1E20 cm | 03-05-2015 |
20150076571 | METHOD OF FABRICATING METAL-INSULATOR-SEMICONDUCTOR TUNNELING CONTACTS USING CONFORMAL DEPOSITION AND THERMAL GROWTH PROCESSES - A contact to a source or drain region. The contact has a conductive material, but that conductive material is separated from the source or drain region by an insulator. | 03-19-2015 |
20150084000 | Forming A Non-Planar Transistor Having A Quantum Well Channel - In one embodiment, the present invention includes an apparatus having a substrate, a buried oxide layer formed on the substrate, a silicon on insulator (SOI) core formed on the buried oxide layer, a compressive strained quantum well (QW) layer wrapped around the SOI core, and a tensile strained silicon layer wrapped around the QW layer. Other embodiments are described and claimed. | 03-26-2015 |