Patent application number | Description | Published |
20120132913 | III-V Compound Semiconductor Material Passivation With Crystalline Interlayer - The present disclosure reduces and, in some instances, eliminates the density of interface states in III-V compound semiconductor materials by providing a thin crystalline interlayer onto an upper surface of a single crystal III-V compound semiconductor material layer to protect the crystallinity of the single crystal III-V compound semiconductor material layer's surface atoms prior to further processing of the structure. | 05-31-2012 |
20120187505 | Self-aligned III-V MOSFET fabrication with in-situ III-V epitaxy and in-situ metal epitaxy and contact formation - A method for forming a transistor includes providing a patterned gate stack disposed on a III-V substrate and having sidewall spacers formed on sides of the patterned gate stack, the III-V substrate including source/drain regions adjacent to the sidewall spacers and field oxide regions formed adjacent to the source/drain regions. The method includes growing raised source/drain regions on the source/drain regions, the grown raised source/drain regions including III-V semiconductor material, and growing metal contacts on the grown raised source/drain regions. Another method for forming a transistor includes providing a patterned gate stack disposed on a III-V substrate and having sidewall spacers formed on sides of the patterned gate stack, the III-V substrate including source/drain regions adjacent to the sidewall spacers and field oxide regions formed adjacent to the source/drain regions. The method includes growing metal contacts on the source/drain regions. Transistors and computer program products are also disclosed. | 07-26-2012 |
20120220114 | TENSILE STRESS ENHANCEMENT OF NITRIDE FILM FOR STRESSED CHANNEL FIELD EFFECT TRANSISTOR FABRICATION - A method for inducing a tensile stress in a channel of a field effect transistor (FET) includes forming a nitride film over the FET; forming a contact hole to the FET through the nitride film; and performing ultraviolet (UV) curing of the nitride film after forming the contact hole to the FET through the nitride film, wherein the UV cured nitride film induces the tensile stress in the channel of the FET. | 08-30-2012 |
20120235247 | FIN FIELD EFFECT TRANSISTOR WITH VARIABLE CHANNEL THICKNESS FOR THRESHOLD VOLTAGE TUNING - A method of forming an integrated circuit (IC) includes forming a first and second plurality of spacers on a substrate, wherein the substrate includes a silicon layer, and wherein the first plurality of spacers have a thickness that is different from a thickness of the second plurality of spacers; and etching the silicon layer in the substrate using the first and second plurality of spacers as a mask, wherein the etched silicon layer forms a first plurality and a second plurality of fin field effect transistor (FINFET) channel regions, and wherein the first plurality of FINFET channel regions each have a respective thickness that corresponds to the thickness of the first plurality of spacers, and wherein the second plurality of FINFET channel regions each have a respective thickness that corresponds to the thickness of the second plurality of spacers. | 09-20-2012 |
20120248509 | STRUCTURE AND PROCESS FOR METAL FILL IN REPLACEMENT METAL GATE INTEGRATION - Processes for metal fill in replacement metal gate integration schemes and resultant devices are provided herein. The method includes forming a dummy gate on a semiconductor substrate. The dummy gate includes forming a metal layer between a first material and a second material. The method further includes partially removing the dummy gate to form an opening bounded by a spacer material. The method further includes forming a recess in the spacer material to widen a portion of the opening. The method further includes removing a remaining portion of the dummy gate through the opening to form a trench having the recess forming an upper portion thereof. The method further includes filling the trench and the recess with a replacement metal gate stack. | 10-04-2012 |
20120256294 | Nanopillar Decoupling Capacitor - Techniques for incorporating nanotechnology into decoupling capacitor designs are provided. In one aspect, a decoupling capacitor is provided. The decoupling capacitor comprises a first electrode; an intermediate layer adjacent to the first electrode having a plurality of nanochannels therein; a conformal dielectric layer formed over the intermediate layer and lining the nanochannels; and a second electrode at least a portion of which is formed from an array of nanopillars that fill the nanochannels in the intermediate layer. Methods for fabricating the decoupling capacitor are also provided, as are semiconductor devices incorporating the decoupling capacitor design. | 10-11-2012 |
20120268985 | RESONANCE NANOELECTROMECHANICAL SYSTEMS - Systems and methods for operating a nanometer-scale cantilever beam with a gate electrode. An example system includes a drive circuit coupled to the gate electrode where a drive signal from the circuit may cause the beam to oscillate at or near the beam's resonance frequency. The drive signal includes an AC component, and may include a DC component as well. An alternative example system includes a nanometer-scale cantilever beam, where the beam oscillates to contact a plurality of drain regions. | 10-25-2012 |
20120286375 | PRESERVING STRESS BENEFITS OF UV CURING IN REPLACEMENT GATE TRANSISTOR FABRICATION - A method of forming a semiconductor structure includes forming a stress inducing layer over one or more partially completed field effect transistor (FET) devices disposed over a substrate, the one or more partially completed FET devices including sacrificial dummy gate structures; planarizing the stress inducing layer and removing the sacrificial dummy gate structures; and following the planarizing the stress inducing layer and removing the sacrificial dummy gate structures, performing an ultraviolet (UV) cure of the stress inducing layer so as to enhance a value of an initial applied stress by the stress inducing layer on channel regions of the one or more partially completed FET devices. | 11-15-2012 |
20120292602 | SELF-ALIGNED CARBON ELECTRONICS WITH EMBEDDED GATE ELECTRODE - A device and method for device fabrication includes forming a buried gate electrode in a dielectric substrate and patterning a stack comprising a high dielectric constant layer, a carbon-based semi-conductive layer and a protection layer over the buried gate electrode. An isolation dielectric layer formed over the stack is opened to define recesses in regions adjacent to the stack. The recesses are etched to form cavities and remove a portion of the high dielectric constant layer to expose the carbon-based semi-conductive layer on opposite sides of the buried gate electrode. A conductive material is deposited in the cavities to form self-aligned source and drain regions. | 11-22-2012 |
20120306026 | REPLACEMENT GATE ELECTRODE WITH A TUNGSTEN DIFFUSION BARRIER LAYER - A tungsten barrier portion is employed in a replacement gate structure to block diffusion of material from a metal portion to a work function material portion. The tungsten barrier portion effectively functions as a diffusion barrier layer between the metal portion and the work function material portion so that the composition of the work function material portion is unaffected by anneal and/or usage of the field effect transistor including the replacement gate structure. Thus, the threshold voltage of the field effect transistor can remain stable throughout processing steps and usage in the field. | 12-06-2012 |
20120326228 | SELF-ALIGNED CARBON ELECTRONICS WITH EMBEDDED GATE ELECTRODE - A device and method for device fabrication includes forming a buried gate electrode in a dielectric substrate and patterning a stack comprising a high dielectric constant layer, a carbon-based semi-conductive layer and a protection layer over the buried gate electrode. An isolation dielectric layer formed over the stack is opened to define recesses in regions adjacent to the stack. The recesses are etched to form cavities and remove a portion of the high dielectric constant layer to expose the carbon-based semi-conductive layer on opposite sides of the buried gate electrode. A conductive material is deposited in the cavities to form self-aligned source and drain regions. | 12-27-2012 |
20130020658 | REPLACEMENT GATE ELECTRODE WITH PLANAR WORK FUNCTION MATERIAL LAYERS - In a replacement gate scheme, a continuous material layer is deposited on a bottom surface and a sidewall surface in a gate cavity. A vertical portion of the continuous material layer is removed to form a gate component of which a vertical portion does not extend to a top of the gate cavity. The gate component can be employed as a gate dielectric or a work function material portion to form a gate structure that enhances performance of a replacement gate field effect transistor. | 01-24-2013 |
20130029488 | Single Liner Process to Achieve Dual Stress - Methods for imparting a dual stress property in a stress liner layer of a semiconductor device. The methods include depositing a metal layer over a compressive stress liner layer, applying a masking agent to a portion of the metal layer to produce a masked and unmasked region of the metal layer, etching the unmasked region of the metal layer to remove the metal layer in the unmasked region to thereby expose a corresponding portion of the compressive stress liner layer, removing the mask to expose the metal layer from the masked region, and irradiating the compressive stress liner layer to impart a tensile stress property to the exposed portion of the compressive stress liner layer. Methods are also provided for imparting a compressive-neutral dual stress property in a stress liner layer, as well as for imparting a neutral-tensile dual stress property in a stress liner layer. | 01-31-2013 |
20130048988 | Nanopillar E-Fuse Structure and Process - Techniques for incorporating nanotechnology into electronic fuse (e-fuse) designs are provided. In one aspect, an e-fuse structure is provided. The e-fuse structure includes a first electrode; a dielectric layer on the first electrode having a plurality of nanochannels therein; an array of metal silicide nanopillars that fill the nanochannels in the dielectric layer, each nanopillar in the array serving as an e-fuse element; and a second electrode in contact with the array of metal silicide nanopillars opposite the first electrode. Methods for fabricating the e-fuse structure are also provided as are semiconductor devices incorporating the e-fuse structure. | 02-28-2013 |
20130082348 | Structure and Method to Form Passive Devices in ETSOI Process Flow - Techniques for fabricating passive devices in an extremely-thin silicon-on-insulator (ETSOI) wafer are provided. In one aspect, a method for fabricating one or more passive devices in an ETSOI wafer is provided. The method includes the following steps. The ETSOI wafer having a substrate and an ETSOI layer separated from the substrate by a buried oxide (BOX) is provided. The ETSOI layer is coated with a protective layer. At least one trench is formed that extends through the protective layer, the ETSOI layer and the BOX, and wherein a portion of the substrate is exposed within the trench. Spacers are formed lining sidewalls of the trench. Epitaxial silicon templated from the substrate is grown in the trench. The protective layer is removed from the ETSOI layer. The passive devices are formed in the epitaxial silicon. | 04-04-2013 |
20130087759 | Light Emitting Diode (LED) Using Carbon Materials - Carbon-based light emitting diodes (LEDs) and techniques for the fabrication thereof are provided. In one aspect, a LED is provided. The LED includes a substrate; an insulator layer on the substrate; a first bottom gate and a second bottom gate embedded in the insulator layer; a gate dielectric on the first bottom gate and the second bottom gate; a carbon material on the gate dielectric over the first bottom gate and the second bottom gate, wherein the carbon material serves as a channel region of the LED; and metal source and drain contacts to the carbon material. | 04-11-2013 |
20130087859 | Work Function Adjustment By Carbon Implant In Semiconductor Devices Including Gate Structure - A device including a p-type semiconductor device and an n-type semiconductor device on a semiconductor substrate. The n-type semiconductor device includes a gate structure having a high-k gate dielectric. A carbon dopant in a concentration ranging from 1×10 | 04-11-2013 |
20130093000 | VERTICAL TRANSISTOR HAVING AN ASYMMETRIC GATE - A transistor structure is formed to include a substrate and, overlying the substrate, a source; a drain; and a channel disposed vertically between the source and the drain. The channel is coupled to a gate conductor that surrounds the channel via a layer of gate dielectric material that surrounds the channel. The gate conductor is composed of a first electrically conductive material having a first work function that surrounds a first portion of a length of the channel and a second electrically conductive material having a second work function that surrounds a second portion of the length of the channel. A method to fabricate the transistor structure is also disclosed. The transistor structure can be characterized as being a vertical field effect transistor having an asymmetric gate. | 04-18-2013 |
20130093018 | CARBON IMPLANT FOR WORKFUNCTION ADJUSTMENT IN REPLACEMENT GATE TRANSISTOR - A method includes providing a wafer that has a semiconductor layer having an insulator layer disposed on the semiconductor layer. The insulator layer has openings made therein to expose a surface of the semiconductor layer, where each opening corresponds to a location of what will become a transistor channel in the semiconductor layer disposed beneath a gate stack. The method further includes depositing a high dielectric constant gate insulator layer so as to cover the exposed surface of the semiconductor layer and sidewalls of the insulator layer; depositing a gate metal layer that overlies the high dielectric constant gate insulator layer; and implanting Carbon through the gate metal layer and the underlying high dielectric constant gate insulator layer so as to form in an upper portion of the semiconductor layer a Carbon-implanted region having a concentration of Carbon selected to establish a voltage threshold of the transistor. | 04-18-2013 |
20130093021 | CARBON IMPLANT FOR WORKFUNCTION ADJUSTMENT IN REPLACEMENT GATE TRANSISTOR - A transistor includes a semiconductor body having a channel formed in the semiconductor body; a high dielectric constant gate insulator layer disposed over a surface of an upper portion of the channel; and a gate metal layer disposed over the high dielectric constant gate insulator layer. The channel contains Carbon implanted through the gate metal layer, the high dielectric constant gate insulator layer and the surface to form in the upper portion of the channel a Carbon-implanted region having a substantially uniform concentration of Carbon selected to establish a voltage threshold of the transistor. | 04-18-2013 |
20130095623 | VERTICAL TRANSISTOR HAVING AN ASYMMETRIC GATE - A transistor structure is formed to include a substrate and, overlying the substrate, a source; a drain; and a channel disposed vertically between the source and the drain. The channel is coupled to a gate conductor that surrounds the channel via a layer of gate dielectric material that surrounds the channel. The gate conductor is composed of a first electrically conductive material having a first work function that surrounds a first portion of a length of the channel and a second electrically conductive material having a second work function that surrounds a second portion of the length of the channel. A method to fabricate the transistor structure is also disclosed. The transistor structure can be characterized as being a vertical field effect transistor having an asymmetric gate. | 04-18-2013 |
20130099313 | FINFET STRUCTURE AND METHOD TO ADJUST THRESHOLD VOLTAGE IN A FINFET STRUCTURE - FinFET structures and methods of manufacturing the FinFET structures are disclosed. The method includes performing an oxygen anneal process on a gate stack of a FinFET structure to induce Vt shift. The oxygen anneal process is performed after sidewall pull down and post silicide. | 04-25-2013 |
20130105894 | THRESHOLD VOLTAGE ADJUSTMENT FOR THIN BODY MOSFETS | 05-02-2013 |
20130105896 | Threshold Voltage Adjustment For Thin Body Mosfets | 05-02-2013 |
20130115732 | Method to Fabricate Multicrystal Solar Cell with Light Trapping Surface Using Nanopore Copolymer - Multi-crystalline silicon processing techniques are provided. In one aspect, a method for roughening a multi-crystalline silicon surface is provided. The method includes the following steps. The multi-crystalline silicon surface is coated with a diblock copolymer. The diblock copolymer is annealed to form nanopores therein. The multi-crystalline silicon surface is etched through the nanopores in the diblock copolymer to roughen the multi-crystalline silicon surface. The diblock copolymer is removed. A multi-crystalline silicon substrate with a roughened surface having a plurality of peaks and troughs is also provided, wherein a distance from one peak to an adjacent peak on the roughened surface is from about 20 nm to about 400 nm. | 05-09-2013 |
20130126830 | TRANSISTOR EMPLOYING VERTICALLY STACKED SELF-ALIGNED CARBON NANOTUBES - A fin structure including a vertical alternating stack of a first isoelectric point material layer having a first isoelectric point and a second isoelectric material layer having a second isoelectric point less than the first isoelectric point is formed. The first and second isoelectric point material layers become oppositely charged in a solution with a pH between the first and second isoelectric points. Negative electrical charges are imparted onto carbon nanotubes by an anionic surfactant to the solution. The electrostatic attraction causes the carbon nanotubes to be selectively attached to the surfaces of the first isoelectric point material layer. Carbon nanotubes are attached to the first isoelectric point material layer in self-alignment along horizontal lengthwise directions of the fin structure. A transistor can be formed, which employs a plurality of vertically aligned horizontal carbon nanotubes as the channel. | 05-23-2013 |
20130130446 | TRANSISTOR EMPLOYING VERTICALLY STACKED SELF-ALIGNED CARBON NANOTUBES - A fin structure including a vertical alternating stack of a first isoelectric point material layer having a first isoelectric point and a second isoelectric material layer having a second isoelectric point less than the first isoelectric point is formed. The first and second isoelectric point material layers become oppositely charged in a solution with a pH between the first and second isoelectric points. Negative electrical charges are imparted onto carbon nanotubes by an anionic surfactant to the solution. The electrostatic attraction causes the carbon nanotubes to be selectively attached to the surfaces of the first isoelectric point material layer. Carbon nanotubes are attached to the first isoelectric point material layer in self-alignment along horizontal lengthwise directions of the fin structure. A transistor can be formed, which employs a plurality of vertically aligned horizontal carbon nanotubes as the channel. | 05-23-2013 |
20130153964 | FETs with Hybrid Channel Materials - Techniques for employing different channel materials within the same CMOS circuit are provided. In one aspect, a method of fabricating a CMOS circuit includes the following steps. A wafer is provided having a first semiconductor layer on an insulator. STI is used to divide the first semiconductor layer into a first active region and a second active region. The first semiconductor layer is recessed in the first active region. A second semiconductor layer is epitaxially grown on the first semiconductor layer, wherein the second semiconductor layer comprises a material having at least one group III element and at least one group V element. An n-FET is formed in the first active region using the second semiconductor layer as a channel material for the n-FET. A p-FET is formed in the second active region using the first semiconductor layer as a channel material for the p-FET. | 06-20-2013 |
20130154001 | EMBEDDED STRESSORS FOR MULTIGATE TRANSISTOR DEVICES - Multigate transistor devices and methods of their fabrication are disclosed. In accordance with one method, a fin and a gate structure that is disposed on a plurality of surfaces of the fin are formed. In addition, at least a portion of an extension of the fin is removed to form a recessed portion that is below the gate structure, is below a channel region of the fin, and includes at least one angled indentation. Further, a terminal extension is grown in the at least one angled indentation below the channel region and along a surface of the channel region such that the terminal extension provides a stress on the channel region to enhance charge carrier mobility in the channel region. | 06-20-2013 |
20130154029 | EMBEDDED STRESSORS FOR MULTIGATE TRANSISTOR DEVICES - Multigate transistor devices and methods of their fabrication are disclosed. In accordance with one method, a fin and a gate structure that is disposed on a plurality of surfaces of the fin are formed. In addition, at least a portion of an extension of the fin is removed to form a recessed portion that is below the gate structure, is below a channel region of the fin, and includes at least one angled indentation. Further, a terminal extension is grown in the at least one angled indentation below the channel region and along a surface of the channel region such that the terminal extension provides a stress on the channel region to enhance charge carrier mobility in the channel region. | 06-20-2013 |
20130168834 | III-V COMPOUND SEMICONDUCTOR MATERIAL PASSIVATION WITH CRYSTALLINE INTERLAYER - The present disclosure reduces and, in some instances, eliminates the density of interface states in III-V compound semiconductor materials by providing a thin crystalline interlayer onto an upper surface of a single crystal III-V compound semiconductor material layer to protect the crystallinity of the single crystal III-V compound semiconductor material layer's surface atoms prior to further processing of the structure. | 07-04-2013 |
20130175620 | FINFET WITH FULLY SILICIDED GATE - A method is provided for fabricating a finFET device. Multiple fin structures are formed over a BOX layer, and a gate stack is formed on the BOX layer. The fin structures each include a semiconductor layer and extend in a first direction, and the gate stack is formed over the fin structures and extends in a second direction. The gate stack includes dielectric and polysilicon layers. Gate spacers are formed on vertical sidewalls of the gate stack, and an epi layer is deposited over the fin structures. Ions are implanted to form source and drain regions, and the gate spacers are etched so that their upper surface is below an upper surface of the gate stack. After etching the gate spacers, silicidation is performed to fully silicide the polysilicon layer of the gate stack and to form silicide regions in an upper surface of the source and drain regions. | 07-11-2013 |
20130175632 | REDUCTION OF CONTACT RESISTANCE AND JUNCTION LEAKAGE - A time clock clearly identifies where a user should position a time card therein. The clock and a printer platen are fixed relative to a base, and has the time card rests thereon. A printing mechanism moves relative to the base and has a target area, it is traversable between a print position and an idle position, and it impresses the time indicia onto the time card while in the print position. A ribbon shield is fixed relative to the base. A focused illuminated guide is fixed relative to the base, and in combination with the ribbon shield, guides the time card with respect to the printing mechanism to clearly identify where the user should position the time card in the time clock. | 07-11-2013 |
20130175633 | CONTROLLING THRESHOLD VOLTAGE IN CARBON BASED FIELD EFFECT TRANSISTORS - A field effect transistor fabrication method includes defining a gate structure on a substrate, depositing a dielectric layer on the gate structure, depositing a first metal layer on the dielectric layer, removing a portion of the first metal layer, depositing a second metal layer, annealing the first and second metal layers, and defining a carbon based device on the dielectric layer and the gate structure. | 07-11-2013 |
20130175642 | SCALING OF METAL GATE WITH ALUMINUM CONTAINING METAL LAYER FOR THRESHOLD VOLTAGE SHIFT - A method of forming a p-type semiconductor device is provided, which in one embodiment employs an aluminum containing threshold voltage shift layer to produce a threshold voltage shift towards the valence band of the p-type semiconductor device. The method of forming the p-type semiconductor device may include forming a gate structure on a substrate, in which the gate structure includes a gate dielectric layer in contact with the substrate, an aluminum containing threshold voltage shift layer present on the gate dielectric layer, and a metal containing layer in contact with at least one of the aluminum containing threshold voltage shift layer and the gate dielectric layer. P-type source and drain regions may be formed in the substrate adjacent to the portion of the substrate on which the gate structure is present. A p-type semiconductor device provided by the above-described method is also provided. | 07-11-2013 |
20130178020 | FINFET WITH FULLY SILICIDED GATE - A method is provided for fabricating a finFET device. Multiple fin structures are formed over a BOX layer, and a gate stack is formed on the BOX layer. The fin structures each include a semiconductor layer and extend in a first direction, and the gate stack is formed over the fin structures and extends in a second direction. The gate stack includes dielectric and polysilicon layers. Gate spacers are formed on vertical sidewalls of the gate stack, and an epi layer is deposited over the fin structures. Ions are implanted to form source and drain regions, and the gate spacers are etched so that their upper surface is below an upper surface of the gate stack. After etching the gate spacers, silicidation is performed to fully silicide the polysilicon layer of the gate stack and to form silicide regions in an upper surface of the source and drain regions. | 07-11-2013 |
20130200468 | Integration of SMT in Replacement Gate FINFET Process Flow - A method of fabricating a FINFET includes the following steps. A plurality of fins is patterned in a wafer. A dummy gate is formed covering a portion of the fins which serves as a channel region. Spacers are formed on opposite sides of the dummy gate. The dummy gate is removed thus forming a trench between the spacers that exposes the fins in the channel region. A nitride material is deposited into the trench so as to cover a top and sidewalls of each of the fins in the channel region. The wafer is annealed to induce strain in the nitride material thus forming a stressed nitride film that covers and induces strain in the top and the sidewalls of each of the fins in the channel region of the device. The stressed nitride film is removed. A replacement gate is formed covering the fins in the channel region. | 08-08-2013 |
20130207194 | TRANSISTORS WITH UNIAXIAL STRESS CHANNELS - A method for fabricating a transistor with uniaxial stress channels includes depositing an insulating layer onto a substrate, defining bars within the insulating layer, recessing a channel into the substrate, growing a first semiconducting material in the channel, defining a gate stack over the bars and semiconducting material, defining source and drain recesses and embedding a second semiconducting material into the source and drain recesses. | 08-15-2013 |
20130244386 | SELF-ALIGNED CARBON ELECTRONICS WITH EMBEDDED GATE ELECTRODE - A device and method for device fabrication includes forming a buried gate electrode in a dielectric substrate and patterning a stack that includes a high dielectric constant layer, a carbon-based semi-conductive layer and a protection layer over the buried gate electrode. An isolation dielectric layer formed over the stack is opened to define recesses in regions adjacent to the stack. The recesses are etched to form cavities and remove a portion of the high dielectric constant layer to expose the carbon-based semi-conductive layer on opposite sides of the buried gate electrode. A conductive material is deposited in the cavities to form self-aligned source and drain regions. | 09-19-2013 |
20130285156 | FIN FIELD EFFECT TRANSISTOR WITH VARIABLE CHANNEL THICKNESS FOR THRESHOLD VOLTAGE TUNING - A method of forming an integrated circuit (IC) includes forming a first and second plurality of spacers on a substrate, wherein the substrate includes a silicon layer, and wherein the first plurality of spacers have a thickness that is different from a thickness of the second plurality of spacers; and etching the silicon layer in the substrate using the first and second plurality of spacers as a mask, wherein the etched silicon layer forms a first plurality and a second plurality of fin field effect transistor (FINFET) channel regions, and wherein the first plurality of FINFET channel regions each have a respective thickness that corresponds to the thickness of the first plurality of spacers, and wherein the second plurality of FINFET channel regions each have a respective thickness that corresponds to the thickness of the second plurality of spacers. | 10-31-2013 |
20130307089 | Self-Aligned III-V MOSFET Fabrication With In-Situ III-V Epitaxy And In-Situ Metal Epitaxy And Contact Formation - A method for forming a transistor includes providing a patterned gate stack disposed on a III-V substrate and having sidewall spacers formed on sides of the patterned gate stack, the III-V substrate including source/drain regions adjacent to the sidewall spacers and field oxide regions formed adjacent to the source/drain regions. The method includes growing raised source/drain regions on the source/drain regions, the grown raised source/drain regions including III-V semiconductor material, and growing metal contacts on the grown raised source/drain regions. Another method for forming a transistor includes providing a patterned gate stack disposed on a III-V substrate and having sidewall spacers formed on sides of the patterned gate stack, the III-V substrate including source/drain regions adjacent to the sidewall spacers and field oxide regions formed adjacent to the source/drain regions. The method includes growing metal contacts on the source/drain regions. Transistors and computer program products are also disclosed. | 11-21-2013 |
20130309830 | Self-Aligned III-V MOSFET Fabrication with In-Situ III-V Epitaxy And In-Situ Metal Epitaxy And Contact Formation - A method for forming a transistor includes providing a patterned gate stack disposed on a III-V substrate and having sidewall spacers formed on sides of the patterned gate stack, the III-V substrate including source/drain regions adjacent to the sidewall spacers and field oxide regions formed adjacent to the source/drain regions. The method includes growing raised source/drain regions on the source/drain regions, the grown raised source/drain regions including III-V semiconductor material, and growing metal contacts on the grown raised source/drain regions. Another method for forming a transistor includes providing a patterned gate stack disposed on a III-V substrate and having sidewall spacers formed on sides of the patterned gate stack, the III-V substrate including source/drain regions adjacent to the sidewall spacers and field oxide regions formed adjacent to the source/drain regions. The method includes growing metal contacts on the source/drain regions. Transistors and computer program products are also disclosed. | 11-21-2013 |
20130328135 | PREVENTING FULLY SILICIDED FORMATION IN HIGH-K METAL GATE PROCESSING - A gate stack structure for a transistor device includes a gate dielectric layer formed over a substrate; a first silicon gate layer formed over the gate dielectric layer; a dopant-rich monolayer formed over the first silicon gate layer; and a second silicon gate layer formed over the dopant-rich monolayer, wherein the dopant-rich monolayer prevents silicidation of the first silicon gate layer during silicidation of the second silicon gate layer. | 12-12-2013 |
20130330899 | PREVENTING FULLY SILICIDED FORMATION IN HIGH-K METAL GATE PROCESSING - A method of forming gate stack structure for a transistor device includes forming a gate dielectric layer over a substrate; forming a first silicon gate layer over the gate dielectric layer; forming a dopant-rich monolayer over the first silicon gate layer; and forming a second silicon gate layer over the dopant-rich monolayer, wherein the dopant-rich monolayer prevents silicidation of the first silicon gate layer during silicidation of the second silicon gate layer. | 12-12-2013 |
20130334602 | CONTINUOUSLY SCALABLE WIDTH AND HEIGHT SEMICONDUCTOR FINS - Arbitrarily and continuously scalable on-currents can be provided for fin field effect transistors by providing two independent variables for physical dimensions for semiconductor fins that are employed for the fin field effect transistors. A recessed region is formed on a semiconductor layer over a buried insulator layer. A dielectric cap layer is formed over the semiconductor layer. Disposable mandrel structures are formed over the dielectric cap layer and spacer structures are formed around the disposable mandrel structures. Selected spacer structures can be structurally damaged during a masked ion implantation. An etch is employed to remove structurally damaged spacer structures at a greater etch rate than undamaged spacer structures. After removal of the disposable mandrel structures, the semiconductor layer is patterned into a plurality of semiconductor fins having different heights and/or different width. Fin field effect transistors having different widths and/or heights can be subsequently formed. | 12-19-2013 |
20140042561 | REPLACEMENT GATE ELECTRODE WITH PLANAR WORK FUNCTION MATERIAL LAYERS - In a replacement gate scheme, a continuous material layer is deposited on a bottom surface and a sidewall surface in a gate cavity. A vertical portion of the continuous material layer is removed to form a gate component of which a vertical portion does not extend to a top of the gate cavity. The gate component can be employed as a gate dielectric or a work function material portion to form a gate structure that enhances performance of a replacement gate field effect transistor. | 02-13-2014 |
20140061857 | PARTIALLY-BLOCKED WELL IMPLANT TO IMPROVE DIODE IDEALITY WITH SiGe ANODE - A method of manufacturing a semiconductor device is disclosed. A p-type substrate is doped to form an N-well in a selected portion of a p-type substrate adjacent an anode region of the substrate. A p-type doped region is formed in the anode region of the p-type substrate. The p-type doped region and the N-well form a p-n junction. | 03-06-2014 |
20140065807 | PARTIALLY-BLOCKED WELL IMPLANT TO IMPROVE DIODE IDEALITY WITH SiGe ANODE - A method of manufacturing a semiconductor device is disclosed. A p-type substrate is doped to form an N-well in a selected portion of a p-type substrate adjacent an anode region of the substrate. A p-type doped region is formed in the anode region of the p-type substrate. The p-type doped region and the N-well form a p-n junction. | 03-06-2014 |
20140124861 | TRANSISTORS WITH UNIAXIAL STRESS CHANNELS - A method for fabricating a transistor with uniaxial stress channels includes depositing an insulating layer onto a substrate, defining bars within the insulating layer, recessing a channel into the substrate, growing a first semiconducting material in the channel, defining a gate stack over the bars and semiconducting material, defining source and drain recesses and embedding a second semiconducting material into the source and drain recesses. | 05-08-2014 |
20140131802 | Structure and Method to Form Passive Devices in ETSOI Process Flow - Techniques for fabricating passive devices in an extremely-thin silicon-on-insulator (ETSOI) wafer are provided. In one aspect, a method for fabricating one or more passive devices in an ETSOI wafer is provided. The method includes the following steps. The ETSOI wafer having a substrate and an ETSOI layer separated from the substrate by a buried oxide (BOX) is provided. The ETSOI layer is coated with a protective layer. At least one trench is formed that extends through the protective layer, the ETSOI layer and the BOX, and wherein a portion of the substrate is exposed within the trench. Spacers are formed lining sidewalls of the trench. Epitaxial silicon templated from the substrate is grown in the trench. The protective layer is removed from the ETSOI layer. The passive devices are formed in the epitaxial silicon. | 05-15-2014 |
20140151786 | NON-VOLATILE GRAPHENE NANOMECHANICAL SWITCH - Non-volatile switches and methods for making the same include a gate material formed in a recess of a substrate; a flexible conductive element disposed above the gate material, separated from the gate material by a gap, where the flexible conductive element is supported on at least two points across the gap, and where a voltage above a gate threshold voltage causes a deformation in the flexible conductive element such that the flexible conductive element comes into contact with a drain in the substrate, thereby closing a circuit between the drain and a source terminal. The gap separating the flexible conductive element and the gate material is sized to create a negative threshold voltage at the gate material for opening the circuit. | 06-05-2014 |
20140154851 | NON-VOLATILE GRAPHENE NANOMECHANICAL SWITCH - Methods for making non-volatile switches include depositing gate material in a recess of a substrate; depositing drain metal in a recess of the gate material; planarizing the gate material, drain metal, and substrate; forming sidewalls by depositing material on the substrate around the gate material; forming a flexible conductive element between the sidewalls to establish a gap between the flexible conductive element and the gate material, such that the gap separating the flexible conductive element and the gate material is sized to create a negative threshold voltage at the gate material for opening a circuit; and forming a source terminal in electrical contact with the flexible conductive element. | 06-05-2014 |
20140191297 | STRAINED FINFET WITH AN ELECTRICALLY ISOLATED CHANNEL - A fin structure includes an optional doped well, a disposable single crystalline semiconductor material portion, and a top semiconductor portion formed on a substrate. A disposable gate structure straddling the fin structure is formed, and end portions of the fin structure are removed to form end cavities. Doped semiconductor material portions are formed on sides of a stack of the disposable single crystalline semiconductor material portion and a channel region including the top semiconductor portion. The disposable single crystalline semiconductor material portion may be replaced with a dielectric material portion after removal of the disposable gate structure or after formation of the stack. The gate cavity is filled with a gate dielectric and a gate electrode. The channel region is stressed by the doped semiconductor material portions, and is electrically isolated from the substrate by the dielectric material portion. | 07-10-2014 |
20140203361 | EXTREMELY THIN SEMICONDUCTOR-ON-INSULATOR FIELD-EFFECT TRANSISTOR WITH AN EPITAXIAL SOURCE AND DRAIN HAVING A LOW EXTERNAL RESISTANCE - An aspect of this invention is a method for fabricating an extremely thin semiconductor-on-insulator (ETSOI) field-effect transistor (FET) having an epitaxial source and drain. The method includes providing an ETSOI substrate; forming at least one isolation structure on the ETSOI substrate; forming a gate on the ETSOI substrate; forming a spacer-on the ETSOI substrate; and using an epitaxial growth process to provide a raised source/drain structure having a non-uniform concentration of carbon along a vertical axis. | 07-24-2014 |
20140203363 | Extremely Thin Semiconductor-On-Insulator Field-Effect Transistor With An Epitaxial Source And Drain Having A Low External Resistance - An aspect of this invention is a method for fabricating an extremely thin semiconductor-on-insulator (ETSOI) field-effect transistor (FET) having an epitaxial source and drain. The method includes providing an ETSOI substrate; forming at least one isolation structure on the ETSOI substrate; forming a gate on the ETSOI substrate; forming a spacer on the ETSOI substrate; and using an epitaxial growth process to provide a raised source/drain structure having a non-uniform concentration of carbon along a vertical axis. | 07-24-2014 |
20140217481 | PARTIAL SACRIFICIAL DUMMY GATE WITH CMOS DEVICE WITH HIGH-K METAL GATE - A gate structure in a semiconductor device includes: a gate stack formed on a substrate with three sections: a bottom portion, a top portion, and a sacrificial cap layer over the top portion; gate spacers; source and drain regions; a nitride encapsulation over top and sidewalls of the gate stack after removal of the sacrificial cap layer; an organic planarizing layer over the nitride encapsulation, planarizing the encapsulation; and silicidation performed over the source and drain regions and the bottom portion after removal of the nitride encapsulation, the organic planarizing layer, and the top portion of the gate stack. | 08-07-2014 |
20140246727 | WORK FUNCTION ADJUSTMENT BY CARBON IMPLANT IN SEMICONDUCTOR DEVICES INCLUDING GATE STRUCTURE - A device including a p-type semiconductor device and an n-type semiconductor device on a semiconductor substrate. The n-type semiconductor device includes a gate structure having a high-k gate dielectric. A carbon dopant in a concentration ranging from 1×10 | 09-04-2014 |
20140264444 | STRESS-ENHANCING SELECTIVE EPITAXIAL DEPOSITION OF EMBEDDED SOURCE AND DRAIN REGIONS - Shallow trench isolation structures are formed within a semiconductor layer of a substrate to define an active area. The active area is recessed relative to a top surface of the shallow trench isolation structure. A shallow trench isolation (STI) spacer is formed on sidewalls of the shallow trench isolation structure around the periphery of the active area. After formation of a gate stack structure and a gate spacer, trenches are formed such that sidewalls of the trenches are vertically coincident with sidewalls of the gate spacer and the STI spacer. Epitaxial semiconductor material can be deposited into the trenches by selective epitaxy to form an embedded source region and an embedded drain region. Because all surfaces of the trenches are semiconductor surfaces, the entire trenches can be filled with the epitaxial semiconductor material, thereby enabling lateral confinement of stress within a channel region of a field effect transistor. | 09-18-2014 |
20140264558 | FACETED INTRINSIC EPITAXIAL BUFFER LAYER FOR REDUCING SHORT CHANNEL EFFECTS WHILE MAXIMIZING CHANNEL STRESS LEVELS - A faceted intrinsic buffer semiconductor material is deposited on sidewalls of a source trench and a drain trench by selective epitaxy. A facet adjoins each edge at which an outer sidewall of a gate spacer adjoins a sidewall of the source trench or the drain trench. A doped semiconductor material is subsequently deposited to fill the source trench and the drain trench. The doped semiconductor material can be deposited such that the facets of the intrinsic buffer semiconductor material are extended and inner sidewalls of the deposited doped semiconductor material merges in each of the source trench and the drain trench. The doped semiconductor material can subsequently grow upward. Faceted intrinsic buffer semiconductor material portions allow greater outdiffusion of dopants near faceted corners while suppressing diffusion of dopants in regions of uniform width, thereby suppressing short channel effects. | 09-18-2014 |
20140264591 | METHOD AND STRUCTURE FOR DIELECTRIC ISOLATION IN A FIN FIELD EFFECT TRANSISTOR - A finFET and method of fabrication are disclosed. A sacrificial layer is formed on a bulk semiconductor substrate. A top semiconductor layer (such as silicon) is disposed on the sacrificial layer. The bulk semiconductor substrate is recessed in the area adjacent to the transistor gate and a stressor layer is formed in the recessed area. The sacrificial layer is selectively removed and replaced with an insulator, such as a flowable oxide. The insulator provides isolation between the transistor channel and the bulk substrate without the use of dopants. | 09-18-2014 |
20140312412 | SELF ALIGNED EMBEDDED GATE CARBON TRANSISTORS - Transistors with self-aligned source/drain regions and methods for making the same. The methods include forming a gate structure embedded in a recess in a substrate; removing substrate material around the gate structure to create self-aligned source and drain recesses; forming a channel layer over the gate structure and the source and drain recesses; and forming source and drain contacts in the source and drain recesses, wherein the source and drain contacts extend above the channel layer. | 10-23-2014 |
20140312413 | SELF ALIGNED EMBEDDED GATE CARBON TRANSISTORS - Transistors with self-aligned source/drain regions a gate structure embedded in a substrate; self-aligned source and drain contacts embedded in the substrate around the gate structure; and a channel layer over the gate structure and self-aligned source and drain contacts. The source and drain contacts extend above the channel layer. | 10-23-2014 |
20140332860 | STACKED CARBON-BASED FETS - Methods and systems for forming stacked transistors. Such methods include forming a lower channel layer on a substrate; forming a pair of vertically aligned gate regions over the lower channel layer; forming a pair of vertically aligned source regions and a pair of vertically aligned drain regions on the lower channel material, each pair separated by an insulator; forming an upper channel material over the source regions, drain regions, and gate regions; and providing electrical access to the source, drain, and gate regions. | 11-13-2014 |
20140332862 | STACKED CARBON-BASED FETS - Stacked transistor devices include a lower channel layer formed on a substrate; a pair of vertically aligned source regions formed over the lower channel layer, where the pair of source regions are separated by an insulator; a pair of vertically aligned drain regions formed on the lower channel layer, where the pair of drain regions are separated by an insulator; a pair of vertically aligned gate regions formed on the lower gate dielectric layer; and an upper channel layer formed over the source regions, drain regions, and gate regions. | 11-13-2014 |
20140377924 | STRAINED FINFET WITH AN ELECTRICALLY ISOLATED CHANNEL - A fin structure includes an optional doped well, a disposable single crystalline semiconductor material portion, and a top semiconductor portion formed on a substrate. A disposable gate structure straddling the fin structure is formed, and end portions of the fin structure are removed to form end cavities. Doped semiconductor material portions are formed on sides of a stack of the disposable single crystalline semiconductor material portion and a channel region including the top semiconductor portion. The disposable single crystalline semiconductor material portion may be replaced with a dielectric material portion after removal of the disposable gate structure or after formation of the stack. The gate cavity is filled with a gate dielectric and a gate electrode. The channel region is stressed by the doped semiconductor material portions, and is electrically isolated from the substrate by the dielectric material portion. | 12-25-2014 |
20150060770 | Light Emitting Diode (LED) Using Carbon Materials - Carbon-based light emitting diodes (LEDs) and techniques for the fabrication thereof are provided. In one aspect, a LED is provided. The LED includes a substrate; an insulator layer on the substrate; a first bottom gate and a second bottom gate embedded in the insulator layer; a gate dielectric on the first bottom gate and the second bottom gate; a carbon material on the gate dielectric over the first bottom gate and the second bottom gate, wherein the carbon material serves as a channel region of the LED; and metal source and drain contacts to the carbon material. | 03-05-2015 |
20150069513 | SEMICONDUCTOR-ON-INSULATOR DEVICE INCLUDING STAND-ALONE WELL IMPLANT TO PROVIDE JUNCTION BUTTING - A semiconductor device includes a semiconductor-on-insulator (SOI) substrate having a bulk substrate layer, an active semiconductor layer, and a buried insulator layer interposed between the bulk substrate layer and the active semiconductor layer. A first source/drain (S/D) region includes a first stand-alone butting implant having a first butting width. A second S/D region includes a second stand-alone butting implant having a second butting width. A gate well-region is interposed between the first and second S/D regions. The gate well-region has a gate width that is greater than the first and second butting widths. | 03-12-2015 |
20150072481 | SEMICONDUCTOR-ON-INSULATOR DEVICE INCLUDING STAND-ALONE WELL IMPLANT TO PROVIDE JUNCTION BUTTING - A semiconductor device includes a semiconductor-on-insulator (SOI) substrate having a bulk substrate layer, an active semiconductor layer, and a buried insulator layer interposed between the bulk substrate layer and the active semiconductor layer. A first source/drain (S/D) region includes a first stand-alone butting implant having a first butting width. A second S/D region includes a second stand-alone butting implant having a second butting width. A gate well-region is interposed between the first and second S/D regions. The gate well-region has a gate width that is greater than the first and second butting widths. | 03-12-2015 |
20150084096 | FACETED INTRINSIC EPITAXIAL BUFFER LAYER FOR REDUCING SHORT CHANNEL EFFECTS WHILE MAXIMIZING CHANNEL STRESS LEVELS - A faceted intrinsic buffer semiconductor material is deposited on sidewalls of a source trench and a drain trench by selective epitaxy. A facet adjoins each edge at which an outer sidewall of a gate spacer adjoins a sidewall of the source trench or the drain trench. A doped semiconductor material is subsequently deposited to fill the source trench and the drain trench. The doped semiconductor material can be deposited such that the facets of the intrinsic buffer semiconductor material are extended and inner sidewalls of the deposited doped semiconductor material merges in each of the source trench and the drain trench. The doped semiconductor material can subsequently grow upward. Faceted intrinsic buffer semiconductor material portions allow greater outdiffusion of dopants near faceted corners while suppressing diffusion of dopants in regions of uniform width, thereby suppressing short channel effects. | 03-26-2015 |