Patent application number | Description | Published |
20110215405 | PREVENTION OF OXYGEN ABSORPTION INTO HIGH-K GATE DIELECTRIC OF SILICON-ON-INSULATOR BASED FINFET DEVICES - A method of forming fin field effect transistor (finFET) devices includes forming a plurality of semiconductor fins over a buried oxide (BOX) layer; performing a nitrogen implant so as to formed nitrided regions in a upper portion of the BOX layer corresponding to regions between the plurality of semiconductor fins; forming a gate dielectric layer over the semiconductor fins and the nitrided regions of the upper portion of the BOX layer; and forming one or more gate electrode materials over the gate dielectric layer; wherein the presence of the nitrided regions of upper portion of the BOX layer prevents oxygen absorption into the gate dielectric layer as a result of thermal processing. | 09-08-2011 |
20120038007 | Field Effect Transistor Device With Self-Aligned Junction - A method for fabricating a field effect transistor device includes forming a dummy gate stack on a first portion of a substrate, forming a source region and a drain region adjacent to the dummy gate stack, forming a ion doped source extension portion in the substrate, the source extension portion extending from the source region into the first portion of the substrate, forming an ion doped drain extension portion in the substrate, the drain extension portion extending from the drain region into the first portion of the substrate, removing a portion of the dummy gate stack to expose an interfacial layer of the dummy gate stack, implanting ions in the source extension portion and the drain extension portion to form a channel region in the first portion of the substrate, removing the interfacial layer, and forming a gate stack on the channel region of the substrate. | 02-16-2012 |
20120038008 | Field Effect Transistor Device with Self-Aligned Junction and Spacer - In one aspect of the present invention, a method for fabricating a field effect transistor device includes forming a dummy gate stack on a first portion of a substrate, forming a source region and a drain region adjacent to the dummy gate stack, forming a ion doped source extension portion in the substrate, forming an ion doped drain extension portion in the substrate, forming a first spacer portion adjacent to the dummy gate stack, removing the dummy gate stack to expose a channel region of the substrate, a portion of the ion doped source extension portion, and a portion of the ion doped drain extension portion, forming a second spacer portion on the exposed portion of the ion doped source extension portion and on the exposed portion of the ion doped drain extension portion, and forming a gate stack on the exposed channel region of the substrate. | 02-16-2012 |
20120193712 | FinFET STRUCTURE HAVING FULLY SILICIDED FIN - A semiconductor device which includes fins of a semiconductor material formed on a semiconductor substrate and then a gate electrode formed over and in contact with the fins. An insulator layer is deposited over the gate electrode and the fins. A trench opening is then etched in the insulator layer. The trench opening exposes the fins and extends between the fins. The fins are then silicided through the trench opening. Then, the trench opening is filled with a metal in contact with the silicided fins to form a local interconnect connecting the fins. | 08-02-2012 |
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 |
20120286360 | Field Effect Transistor Device with Self-Aligned Junction and Spacer - A field effect transistor device includes a substrate including a source region, a drain region, and a channel region disposed between the source region and the drain region, wherein the source region is connected to the channel region with a source extension portion, and the drain region is connected to the channel region with a drain extension portion, a first spacer portion disposed on the source region, the drain region and a first portion of the source extension portion, and a first portion of the drain extension portion, a second spacer portion disposed on a second portion of the source extension portion, and a second portion of the drain extension portion, a gate stack portion disposed on the channel region. | 11-15-2012 |
20120286371 | Field Effect Transistor Device With Self-Aligned Junction - A field effect transistor device includes a substrate including a source region, a drain region, and a channel region disposed between the source region and the drain region, wherein the source region is connected to the channel region with a source extension portion, and the drain region is connected to the channel region with a drain extension portion, wherein the channel region includes a source transition portion including n-type and p-type ions and a drain transition portion including n-type and p-type ions, and a gate stack portion disposed on the channel region. | 11-15-2012 |
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 |
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 |
20130082329 | MULTI-GATE FIELD-EFFECT TRANSISTORS WITH VARIABLE FIN HEIGHTS - Multi-gate devices and methods of their fabrication are disclosed. A multi-gate device can include a gate structure and a plurality of fins. The gate structure envelops a plurality of surfaces of the fins, which are directly on a substrate that is composed of a semiconducting material. Each of the fins provides a channel between a respective source and a respective drain, is composed of the semiconducting material and is doped. A first fin of the plurality of fins has a first height that is different from a second height of a second fin of the plurality of fins such that drive currents of the first and second fins are different. Further, the first and second fins form a respective cohesive structure of the semiconducting material with the substrate. In addition, surfaces of the substrate that border the fins are disposed at a same vertical position. | 04-04-2013 |
20130082333 | MULTI-GATE FIELD-EFFECT TRANSISTORS WITH VARIABLE FIN HEIGHTS - Multi-gate devices and methods of their fabrication are disclosed. A multi-gate device can include a gate structure and a plurality of fins. The gate structure envelops a plurality of surfaces of the fins, which are directly on a substrate that is composed of a semiconducting material. Each of the fins provides a channel between a respective source and a respective drain, is composed of the semiconducting material and is doped. A first fin of the plurality of fins has a first height that is different from a second height of a second fin of the plurality of fins such that drive currents of the first and second fins are different. Further, the first and second fins form a respective cohesive structure of the semiconducting material with the substrate. In addition, surfaces of the substrate that border the fins are disposed at a same vertical position. | 04-04-2013 |
20130105894 | THRESHOLD VOLTAGE ADJUSTMENT FOR THIN BODY MOSFETS | 05-02-2013 |
20130105896 | Threshold Voltage Adjustment For Thin Body Mosfets | 05-02-2013 |
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 |
20130154005 | SOI FINFET WITH RECESSED MERGED FINS AND LINER FOR ENHANCED STRESS COUPLING - FinFETS and methods for making FinFETs with a recessed stress liner. A method includes providing an SW substrate with fins, forming a gate over the fins, forming an off-set spacer on the gate, epitaxially growing a film to merge the fins, depositing a dummy spacer around the gate, and recessing the merged epi film. Silicide is then formed on the recessed merged epi film followed by deposition of a stress liner film over the FinFET. By using a recessed merged epi process, a MOSFET with a vertical silicide (i.e. perpendicular to the substrate) can be formed. The perpendicular silicide improves spreading resistance. | 06-20-2013 |
20130154006 | FINFET WITH VERTICAL SILICIDE STRUCTURE - FinFETS and methods for making FinFETs with a vertical silicide structure. A method includes providing a substrate with a plurality of fins, forming a gate stack above the substrate wherein the gate stack has at least one sidewall and forming an off-set spacer adjacent the gate stack sidewall. The method also includes growing an epitaxial film which merges the fins to form an epi-merge layer, forming a field oxide layer adjacent to at least a portion of the off-set spacer and removing a portion of the field oxide layer to expose a portion of the epi-merge-layer. The method further includes removing at least part of the exposed portion of the epi-merge-layer to form an epi-merge sidewall and an epi-merge spacer region and forming a silicide within the epi-merge sidewall to form a silicide layer and two silicide sidewalls. | 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 |
20130161744 | FINFET WITH MERGED FINS AND VERTICAL SILICIDE - A finFET device is provided. The finFET device includes a BOX layer, fin structures located over the BOX layer, a gate stack located over the fin structures, gate spacers located on vertical sidewalls of the gate stack, an epi layer covering the fin structures, source and drain regions located in the semiconductor layers of the fin structures, and silicide regions abutting the source and drain regions. The fin structures each comprise a semiconductor layer and extend in a first direction, and the gate stack extends in a second direction that is perpendicular. The gate stack comprises a high-K dielectric layer and a metal gate, and the epi layer merges the fin structures together. The silicide regions each include a vertical portion located on the vertical sidewall of the source or drain region. | 06-27-2013 |
20130164890 | METHOD FOR FABRICATING FINFET WITH MERGED FINS AND VERTICAL SILICIDE - A method is provided for fabricating a finFET device. Fin structures are formed over a BOX layer. The fin structures include a semiconductor layer and extend in a first direction. A gate stack is formed on the BOX layer over the fin structures and extending in a second direction. The gate stack includes a high-K dielectric layer and a metal gate. Gate spacers are formed on sidewalls of the gate stack, and an epi layer is deposited to merge the fin structures. Ions are implanted to form source and drain regions, and dummy spacers are formed on sidewalls of the gate spacers. The dummy spacers are used as a mask to recess or completely remove an exposed portion of the epi layer. Silicidation forms silicide regions that abut the source and drain regions and each include a vertical portion located on the vertical sidewall of the source or drain region. | 06-27-2013 |
20130175594 | INTEGRATED CIRCUIT INCLUDING DRAM AND SRAM/LOGIC - An integrated circuit comprising an N+ type layer, a buffer layer arranged on the N+ type layer; a P type region formed on with the buffer layer; an insulator layer overlying the N+ type layer, a silicon layer overlying the insulator layer, an embedded RAM FET formed in the silicon layer and connected with a conductive node of a trench capacitor that extends into the N+ type layer, the N+ type layer forming a plate electrode of the trench capacitor, a first contact through the silicon layer and the insulating layer and electrically connecting to the N+ type layer, a first logic RAM FET formed in the silicon layer above the P type region, the P type region functional as a P-type back gate of the first logic RAM FET, and a second contact through the silicon layer and the insulating layer and electrically connecting to the P type region. | 07-11-2013 |
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 |
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 |
20130264653 | STRUCTURE AND METHOD OF HIGH-PERFORMANCE EXTREMELY THIN SILICON ON INSULATOR COMPLEMENTARY METAL-OXIDE-SEMICONDUCTOR TRANSISTORS WITH DUAL STRESS BURIED INSULATORS - A method of forming a complementary metal oxide semiconductor (CMOS) device including an n-type field effect transistor (NFET) and an p-type field effect transistor (PFET) having fully silicided gates electrode in which an improved dual stress buried insulator is employed to incorporate and advantageous mechanical stress into the device channel of the NFET and PFET. The method can be imposed on a bulk substrate or extremely thin silicon on insulator (ETSOI) substrate. The device includes a semiconductor substrate, a plurality of shallow trench isolations structures formed in the ETSOI layer, NFET having a source and drain region and a gate formation, a PFET having a source and drain region, and a gate formation, an insulator layer, including a stressed oxide or nitride, deposited inside the substrate of the NFET, and a second insulator layer, including either an stressed oxide or nitride, deposited inside the substrate of the PFET. | 10-10-2013 |
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 |
20130307079 | ETCH RESISTANT BARRIER FOR REPLACEMENT GATE INTEGRATION - Semiconductor devices and methods of their fabrication are disclosed. One device includes a plurality of gates and a dielectric gap filling material with a pre-determined aspect ratio that is between the gates. The device further includes an etch resistant nitride layer that is configured to maintain the aspect ratio of the dielectric gap filling material during fabrication of the device and is disposed above the dielectric gap filling material and between the plurality of gates. | 11-21-2013 |
20130307121 | RETROGRADE SUBSTRATE FOR DEEP TRENCH CAPACITORS - A semiconductor device includes a substrate having a first doped portion to a first depth and a second doped portion below the first depth. A deep trench capacitor is formed in the substrate and extends below the first depth. The deep trench capacitor has a buried plate that includes a dopant type forming an electrically conductive connection with second doped portion of the substrate and being electrically insulated from the first doped portion. | 11-21-2013 |
20130309835 | RETROGRADE SUBSTRATE FOR DEEP TRENCH CAPACITORS - A method for forming a semiconductor device includes forming a deep trench in a substrate having a first doped portion to a first depth and a second doped portion below the first depth, the deep trench extending below the first depth. A region around the deep trench is doped to form a buried plate where the buried plate includes a dopant type forming an electrically conductive connection with the second doped portion of the substrate and being electrically insulated from the first doped portion. A deep trench capacitor is formed in the deep trench using the buried plate as one electrode of the capacitor. An access transistor is formed to charge or discharge the deep trench capacitor. A well is formed in the first doped portion. | 11-21-2013 |
20130309856 | ETCH RESISTANT BARRIER FOR REPLACEMENT GATE INTEGRATION - Semiconductor devices and methods of their fabrication are disclosed. One method includes forming a semiconductor device structure including a plurality of dummy gates and a dielectric gap filling material with a pre-determined aspect ratio that is between the dummy gates. An etch resistant nitride layer is applied above the dielectric gap filling material to maintain the aspect ratio of the gap filling material. In addition, the dummy gates are removed by implementing an etching process. Further, replacement gates are formed in regions of the device structure previously occupied by the dummy gates. | 11-21-2013 |
20130313649 | FIN ISOLATION FOR MULTIGATE TRANSISTORS - Multigate transistor devices and methods of their fabrication are disclosed. One such device includes a plurality of semiconductor fins that have source and drain regions and a gate structure overlaying the fins. The device further includes a dielectric layer that is beneath the gate structure and the fins. Here, the dielectric layer includes first dielectric regions that are disposed beneath the fins and second dielectric regions that are disposed between the fins. In addition, the first dielectric regions have a density that is greater than a density of the second dielectric regions. | 11-28-2013 |
20130316513 | FIN ISOLATION FOR MULTIGATE TRANSISTORS - Multigate transistor devices and methods of their fabrication are disclosed. In one method, a substrate including a semiconductor upper layer and a lower layer beneath the upper layer is provided. The lower layer has a rate of transformation into a dielectric that is higher than a rate of transformation into a dielectric of the upper layer when the upper and lower layers are subjected to dielectric transformation conditions. Fins are formed in the upper layer, and the lower layer beneath the fins is transformed into a dielectric material to electrically isolate the fins. In addition, a gate structure is formed over the fins to complete the multigate transistor device. | 11-28-2013 |
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 |
20140027831 | Method of eDRAM DT Strap Formation in FinFET Device Structure - The specification and drawings present a new method, device and computer/software related product (e.g., a computer readable memory) are presented for realizing eDRAM strap formation in Fin FET device structures. Semiconductor on insulator (SOI) substrate comprising at least an insulator layer between a first semiconductor layer and a second semiconductor layer is provided. The (metal) strap formation is accomplished by depositing conductive layer on fins portion of the second semiconductor layer (Si) and a semiconductor material (polysilicon) in each DT capacitor extending to the second semiconductor layer. The metal strap is sealed by a nitride spacer to prevent the shorts between PWL and DT capacitors. | 01-30-2014 |
20140027878 | SELF-ALIGNED TRENCH OVER FIN - A stack of a first hard mask portion and a second hard mask portion is formed over a semiconductor material layer by anisotropically etching a stack, from bottom to top, of a first hard mask layer and a second hard mask layer. The first hard mask portion is laterally recessed by an isotropic etch. A dielectric material layer is conformally deposited and planarized. The dielectric material layer is etched employing an anisotropic etch that is selective to the first hard mask portion to form a dielectric material portion that laterally surrounds the first hard mask portion. After removal of the second and first hard mask portions, the semiconductor material layer is etched employing the dielectric material portion as an etch mask. Optionally, portions of the semiconductor material layer underneath the first and second hard mask portions can be undercut at a periphery. | 01-30-2014 |
20140027917 | NON-LITHOGRAPHIC LINE PATTERN FORMATION - A metal layer is deposited over an underlying material layer. The metal layer includes an elemental metal that can be converted into a dielectric metal-containing compound by plasma oxidation and/or nitridation. A hard mask portion is formed over the metal layer. Plasma oxidation or nitridation is performed to convert physically exposed surfaces of the metal layer into the dielectric metal-containing compound. The sequence of a surface pull back of the hard mask portion, trench etching, another surface pull back, and conversion of top surfaces into the dielectric metal-containing compound are repeated to form a line pattern having a spacing that is not limited by lithographic minimum dimensions. | 01-30-2014 |
20140027923 | NON-LITHOGRAPHIC HOLE PATTERN FORMATION - A metal layer is deposited over a material layer. The metal layer includes an elemental metal that can be converted into a dielectric metal-containing compound by plasma oxidation or nitridation. A hard mask portion is formed over the metal layer. A plasma impermeable spacer is formed on at least one first sidewall of the hard mask portion, while at least one second sidewall of the hard mask portion is physically exposed. Plasma oxidation or nitridation is performed to convert physically exposed surfaces of the metal layer into the dielectric metal-containing compound. A sequence of a surface pull back of the hard mask portion, cavity etching, another surface pull back, and conversion of top surfaces into the dielectric metal-containing compound are repeated to form a hole pattern having a spacing that is not limited by lithographic minimum dimensions. | 01-30-2014 |
20140030864 | Method of eDRAM DT Strap Formation In FinFET Device Structure - The specification and drawings present a new method, device and computer/software related product (e.g., a computer readable memory) are presented for realizing eDRAM strap formation in Fin FET device structures. Semiconductor on insulator (SOI) substrate comprising at least an insulator layer between a first semiconductor layer and a second semiconductor layer is provided. The (metal) strap formation is accomplished by depositing conductive layer on fins portion of the second semiconductor layer (Si) and a semiconductor material (polysilicon) in each DT capacitor extending to the second semiconductor layer. The metal strap is sealed by a nitride spacer to prevent the shorts between PWL and DT capacitors. | 01-30-2014 |
20140048804 | FIN STRUCTURE FORMATION INCLUDING PARTIAL SPACER REMOVAL - A method of forming a semiconductor device includes forming a mandrel on top of a substrate; forming a first spacer adjacent to the mandrel on top of the substrate; forming a cut mask over the first spacer and the mandrel, such that the first spacer is partially exposed by the cut mask; partially removing the partially exposed first spacer; and etching the substrate to form a fin structure corresponding to the partially removed first spacer in the substrate. | 02-20-2014 |
20140051247 | FIN STRUCTURE FORMATION INCLUDING PARTIAL SPACER REMOVAL - A method of forming a semiconductor device includes forming a mandrel on top of a substrate; forming a first spacer adjacent to the mandrel on top of the substrate; forming a cut mask over the first spacer and the mandrel, such that the first spacer is partially exposed by the cut mask; partially removing the partially exposed first spacer; and etching the substrate to form a fin structure corresponding to the partially removed first spacer in the substrate. | 02-20-2014 |
20140054705 | SILICON GERMANIUM CHANNEL WITH SILICON BUFFER REGIONS FOR FIN FIELD EFFECT TRANSISTOR DEVICE - A fin field effect transistor (finFET) device includes a substrate; first and second source/drain regions located on the substrate; and a fin located on the substrate between the first and second source/drain regions. The fin includes a silicon germanium channel region and first and second silicon buffer regions located in the fin adjacent to and on either side of the silicon germanium channel region. The first silicon buffer region is located between the first source/drain region and the silicon germanium channel region and the second silicon buffer region is located between the second source/drain region and the silicon germanium channel region. | 02-27-2014 |
20140084249 | STACKED NANOWIRE FIELD EFFECT TRANSISTOR - A nanowire field effect transistor device includes a first nanowire having a first distal end connected to a source region, a second distal end connected to a drain region, and a channel region therebetween, the source region and the drain region arranged on a substrate, and a second nanowire having a first distal end connected to the source region and a second distal end connected to the drain region, and a channel region therebetween, a longitudinal axis of the first nanowire and a longitudinal axis of the second nanowire defining a plane, the plane arranged substantially orthogonal to a plane defined by a planar surface of the substrate. | 03-27-2014 |
20140084371 | MULTI-GATE FIELD EFFECT TRANSISTOR DEVICES - A field effect transistor device includes a substrate, a substrate insulator layer arranged on the substrate, a semiconductor fin arranged on the substrate insulator layer, a source region arranged on a portion of the substrate insulator layer, a drain region arranged on a portion of the substrate insulator layer, a first insulator layer portion arranged on the source region, a second insulator layer portion arranged on the drain region, a gate stack arranged about a channel region of the semiconductor fin, and an insulator portion arranged on the gate stack, wherein the insulator portion arranged on the gate stack is disposed between the first insulator layer portion and the second insulator layer portion. | 03-27-2014 |
20140087523 | STACKED NANOWIRE FIELD EFFECT TRANSISTOR - A method for fabricating a nanowire field effect transistor device includes depositing a first sacrificial layer on a substrate, depositing a first layer of a semiconductor material on the first sacrificial layer, depositing a second sacrificial layer on the first layer of semiconductor material, depositing a second layer of the semiconductor material on the second sacrificial layer, pattering and removing portions of the first sacrificial layer, the first semiconductor layer, the second sacrificial layer, and the second semiconductor layer, patterning a dummy gate stack, removing the dummy gate stack, removing portions of the sacrificial layer to define a first nanowire including a portion of the first semiconductor layer and a second nanowire including a portion of the second semiconductor layer, and forming gate stacks about the first nanowire and the second nanowire. | 03-27-2014 |
20140087526 | MULTI-GATE FIELD EFFECT TRANSISTOR DEVICES - A method for fabricating a field effect transistor device includes patterning a semiconductor fin on a substrate insulator layer, the substrate insulator layer arranged on a substrate, patterning a dummy gate stack over a portion of the fin, forming spacers adjacent to the dummy gate stack, removing the dummy gate stack to form a cavity that exposes portions of the substrate insulator layer and the fin, removing exposed portions of the substrate insulator layer to increase a depth of the cavity, removing a region of the substrate insulator layer from beneath the fin to suspend a portion of the fin above the substrate insulator layer, forming a gate stack in the cavity, removing a portion of the gate stack in the cavity to expose a portion of a dielectric layer arranged on the fin, and depositing an insulator material in the cavity. | 03-27-2014 |
20140103435 | VERTICAL SOURCE/DRAIN JUNCTIONS FOR A FINFET INCLUDING A PLURALITY OF FINS - Fin-defining mask structures are formed over a semiconductor material layer. A semiconductor material portion is formed by patterning the semiconductor material layer, and a disposable gate structure is formed over the fin-defining mask structures. After formation of a disposable template layer, the disposable gate structure is removed. A plurality of semiconductor fins are formed by etching center portions of the semiconductor material portion employing the combination of the disposable template layer and the fin-defining mask structures as an etch mask. A first pad region and a second pad region laterally contact the plurality of semiconductor fins. A replacement gate structure is formed on the plurality of semiconductor fins. The disposable template layer is removed, and the first pad region and the second pad regions are vertically recessed. Vertical source/drain junctions can be formed by introducing dopants through vertical sidewalls of the recessed source and second pad regions. | 04-17-2014 |
20140110784 | REPLACEMENT METAL GATE FINFET - A method for fabricating a field effect transistor device includes depositing a hardmask over a semiconductor layer depositing a metallic alloy layer over the hardmask, defining a semiconductor fin, depositing a dummy gate stack material layer conformally on exposed portions of the fin, patterning a dummy gate stack by removing portions of the dummy gate stack material using an etching process that selectively removes exposed portions of the dummy gate stack without appreciably removing portions of the metallic alloy layer, removing exposed portions of the metallic alloy layer, forming spacers adjacent to the dummy gate stack, forming source and drain regions on exposed regions of the semiconductor fin, removing the dummy gate stack, removing exposed portions of the metallic alloy layer, and forming a gate stack conformally over exposed portions of the insulator layer and the semiconductor fin. | 04-24-2014 |
20140110785 | REPLACEMENT METAL GATE FINFET - A field effect transistor device includes a fin including a semiconductor material arranged on an insulator layer, the fin including a channel region, a hardmask layer arranged partially over the channel region of the fin, a gate stack arranged over the hardmask layer and over the channel region of the fin, a metallic alloy layer arranged on a first portion of the hardmask layer, the metallic alloy layer arranged adjacent to the gate stack, and a first spacer arranged adjacent to the gate stack and over the metallic alloy layer. | 04-24-2014 |
20140117490 | SEMICONDUCTOR DEVICE INCLUDING ESD PROTECTION DEVICE - A semiconductor device includes a semiconductor-on-insulator (SOI) substrate having a bulk substrate layer, an active semiconductor layer and a buried insulator layer disposed between the bulk substrate layer and the active semiconductor layer. A trench is formed through the SOI substrate to expose the bulk substrate layer. A doped well is formed in an upper region of the bulk substrate layer adjacent trench. The semiconductor device further includes a first doped region different from the doped well that is formed in the trench. | 05-01-2014 |
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 |
20140145295 | DOUBLE DENSITY SEMICONDUCTOR FINS AND METHOD OF FABRICATION - Methods and structures having increased fin density are disclosed. Structures with two sets of fins are provided. A lower set of fins is interleaved with an upper set of fins in a staggered manner, such that the lower set of fins and upper set of fins are horizontally and vertically non-overlapping. | 05-29-2014 |
20140151773 | FINFET eDRAM STRAP CONNECTION STRUCTURE - A method of forming a strap connection structure for connecting an embedded dynamic random access memory (eDRAM) to a transistor comprises forming a buried oxide layer in a substrate, the buried oxide layer defining an SOI layer on a surface of the substrate; forming a deep trench through the SOI layer and the buried oxide layer in the substrate; forming a storage capacitor in a lower portion of the deep trench; conformally doping a sidewall of an upper portion of the deep trench; depositing a metal strap on the conformally doped sidewall and on the storage capacitor; forming at least one fin in the SOI layer, the fin being in communication with the metal strap; forming a spacer over the metal strap and over a juncture of the fin and the metal strap; and depositing a passive word line on the spacer. | 06-05-2014 |
20140159166 | Preventing FIN Erosion and Limiting Epi Overburden in FinFET Structures by Composite Hardmask - A FinFET structure is formed by forming a hardmask layer on a substrate including a silicon-containing layer on an insulating layer. The hardmask layer includes first, second and third layers on the silicon-containing layer. An array of fins is formed from the hardmask layer and the silicon-containing layer. A gate is formed covering a portion but not all of a length of each of the array of fins. The portion covers each of the fins in the array. The gate defines source/drain regions on either side of the gate. A spacer is formed on each side of the gate, the forming of the spacer performed to remove the third layer from portions of the fins in the source/drain regions. The second layer of the hardmask layer is removed from the portions of the fins in the source/drain regions, and the fins in the source/drain regions are merged. | 06-12-2014 |
20140159167 | PREVENTING FIN EROSION AND LIMITING EPI OVERBURDEN IN FINFET STRUCTURES BY COMPOSITE HARDMASK - A FinFET structure is formed by forming a hardmask layer on a substrate including a silicon-containing layer on an insulating layer. The hardmask layer includes first, second and third layers on the silicon-containing layer. An array of fins is formed from the hardmask layer and the silicon-containing layer. A gate is formed covering a portion but not all of a length of each of the array of fins. The portion covers each of the fins in the array. The gate defines source/drain regions on either side of the gate. A spacer is formed on each side of the gate, the forming of the spacer performed to remove the third layer from portions of the fins in the source/drain regions. The second layer of the hardmask layer is removed from the portions of the fins in the source/drain regions, and the fins in the source/drain regions are merged. | 06-12-2014 |
20140167162 | FINFET WITH MERGE-FREE FINS - A semiconductor device comprises an insulation layer, an active semiconductor layer formed on an upper surface of the insulation layer, and a plurality of fins formed on the insulation layer. The fins are formed in the gate and spacer regions between a first source/drain region and second source/drain region, without extending into the first and second source/drain regions. | 06-19-2014 |
20140170825 | FINFET WITH MERGE-FREE FINS - A semiconductor device comprises an insulation layer, an active semiconductor layer formed on an upper surface of the insulation layer, and a plurality of fins formed on the insulation layer. The fins are formed in the gate and spacer regions between a first source/drain region and second source/drain region, without extending into the first and second source/drain regions. | 06-19-2014 |
20140231890 | MIM CAPACITOR IN FINFET STRUCTURE - A method of forming a FinFET structure having a metal-insulator-metal capacitor. Silicon fins are formed on a semiconductor substrate followed by formation of the metal-insulator-metal capacitor on the silicon fins by depositing sequential layers of a first layer of titanium nitride, a dielectric layer and a second layer of titanium nitride. A polysilicon layer is deposited over the metal-insulator-metal capacitor followed by etching back the polysilicon layer and the metal-insulator-metal capacitor layers from ends of the silicon fins so that the first and second ends of the silicon fins protrude from the polysilicon layer. A spacer may be formed on surfaces facing the ends of the silicon fins followed by the formation of epitaxial silicon over the ends of the silicon fins. Also disclosed is a FinFET structure having a metal-insulator-metal capacitor. | 08-21-2014 |
20140231891 | MIM CAPACITOR IN FINFET STRUCTURE - A FinFET structure which includes: silicon fins on a semiconductor substrate, each silicon fin having two sides and a horizontal surface; sequential layers of a first layer of titanium nitride, a dielectric layer and a second layer of titanium nitride on the sides and horizontal surface of the silicon fins; a polysilicon gate layer over the second layer of titanium nitride on the silicon fins and over the semiconductor substrate such that first and second ends of the silicon fins protrude from the polysilicon layer; spacers adjacent to the polysilicon gate layer; epitaxial silicon over the first and second ends of the silicon fins to form sources and drains, wherein the combination of the first layer of titanium nitride, dielectric layer and second layer of titanium nitride forms a metal-insulator-metal capacitor situated between each silicon fin and the polysilicon layer. | 08-21-2014 |
20140239395 | CONTACT RESISTANCE REDUCTION IN FINFETS - A method for forming contacts in a semiconductor device includes forming a plurality of substantially parallel semiconductor fins on a dielectric layer of a substrate having a gate structure formed transversely to a longitudinal axis of the fins. The fins are merged by epitaxially growing a crystalline material between the fins. A field dielectric layer is deposited over the fins and the crystalline material. Trenches that run transversely to the longitudinal axis of the fins are formed to expose the fins in the trenches. An interface layer is formed over portions of the fins exposed in the trenches. Contact lines are formed in the trenches that contact a top surface of the interface layer on the fins and at least a portion of side surfaces of the interface layer on the fins. | 08-28-2014 |
20140239401 | SILICON NITRIDE GATE ENCAPSULATION BY IMPLANTATION - A FinFET structure which includes: silicon fins on a semiconductor substrate, each silicon fin having two sides and a horizontal surface; a gate wrapping around at least one of the silicon fins, the gate having a first surface and an opposing second surface facing the at least one of the silicon fins; a hard mask on a top surface of the gate; a silicon nitride layer formed in each of the first and second surfaces so as to be below and in direct contact with the hard mask on the top surface of the gate; spacers on the gate and in contact with the silicon nitride layer; and epitaxially deposited silicon on the at least one of the silicon fins so as to form a raised source/drain. | 08-28-2014 |
20140239415 | STRESS MEMORIZATION IN RMG FINFETS - Transistors with memorized stress and methods for making such transistors. The methods include forming a transistor structure having a channel region, a source and drain region, and a gate dielectric; depositing a stressor over the channel region of the transistor structure, wherein the stressor provides a stress to the channel region; removing the stressor metal after the stress is memorized within the channel region; and depositing a work function metal over the channel region of the transistor structure, where the work function metal applies less stress to the channel region than the stress applied by the stressor. A transistor with memorized stress includes a source and drain region on a substrate; a stress-memorized channel region on the substrate that retains an externally applied stress; and a gate structure including a work function gate metal that applies less stress to the stress-memorized channel region than the externally applied stress. | 08-28-2014 |
20140239420 | SILICON NITRIDE GATE ENCAPSULATION BY IMPLANTATION - A method of forming a FinFET structure which includes forming fins on a semiconductor substrate; forming a gate wrapping around at least one of the fins, the gate having a first surface and an opposing second surface facing the fins; depositing a hard mask on a top of the gate; angle implanting nitrogen into the first and second surfaces of the gate so as to form a nitrogen-containing layer in the gate that is below and in direct contact with the hard mask on top of the gate; forming spacers on the gate and in contact with the nitrogen-containing layer; and epitaxially depositing silicon on the at least one fin so as to form a raised source/drain. Also disclosed is a FinFET structure. | 08-28-2014 |
20140256139 | SELF-ALIGNED TRENCH OVER FIN - A stack of a first hard mask portion and a second hard mask portion is formed over a semiconductor material layer by anisotropically etching a stack, from bottom to top, of a first hard mask layer and a second hard mask layer. The first hard mask portion is laterally recessed by an isotropic etch. A dielectric material layer is conformally deposited and planarized. The dielectric material layer is etched employing an anisotropic etch that is selective to the first hard mask portion to form a dielectric material portion that laterally surrounds the first hard mask portion. After removal of the second and first hard mask portions, the semiconductor material layer is etched employing the dielectric material portion as an etch mask. Optionally, portions of the semiconductor material layer underneath the first and second hard mask portions can be undercut at a periphery. | 09-11-2014 |
20140264595 | FORMING STRAINED AND RELAXED SILICON AND SILICON GERMANIUM FINS ON THE SAME WAFER - Various embodiments form strained and relaxed silicon and silicon germanium fins on a semiconductor wafer. In one embodiment a semiconductor wafer is formed. The semiconductor wafer comprises a substrate, a dielectric layer, and a strained silicon germanium (SiGe) layer. At least one region of the strained SiGe layer is transformed into a relaxed SiGe region. At least one strained SiGe fin is formed from a first strained SiGe region of the strained SiGe layer. At least one relaxed SiGe fin is formed from a first portion of the relaxed SiGe region. Relaxed silicon is epitaxially grown on a second strained SiGe region of the strained SiGe layer. Strained silicon is epitaxially grown on a second portion of the relaxed SiGe region. At least one relaxed silicon fin is formed from the relaxed silicon. At least one strained silicon fin is formed from the strained silicon. | 09-18-2014 |
20140264596 | PARTIALLY ISOLATED FIN-SHAPED FIELD EFFECT TRANSISTORS - A transistor device and a method for forming a fin-shaped field effect transistor (FinFET) device, with the channel portion of the fins on buried silicon oxide, while the source and drain portions of the fins on silicon. An example method includes receiving a wafer with a silicon layer electrically isolated from a silicon substrate by a buried oxide (BOX) layer. The BOX layer is in physical contact with the silicon layer and the silicon substrate. The method further comprises implanting a well in the silicon substrate and forming vertical sources and drains over the well between dummy gates. The vertical sources and drains extend through the BOX layer, fins, and a portion of the dummy gates. | 09-18-2014 |
20140264601 | STRAINED SILICON NFET AND SILICON GERMANIUM PFET ON SAME WAFER - Various embodiments form silicon and silicon germanium fins on a semiconductor wafer. In one embodiment a semiconductor wafer is obtained. The semiconductor wafer comprises a substrate, a dielectric layer, and a semiconductor layer including silicon germanium (SiGe). At least one SiGe fin is formed from at least a first SiGe region of the semiconductor layer in at least one PFET region of the semiconductor wafer. Strained silicon is epitaxially grown on at least a second SiGe region of the semiconductor layer. At least one strained silicon fin is formed from the strained silicon in at least one NFET region of the semiconductor wafer. | 09-18-2014 |
20140264602 | FORMING STRAINED AND RELAXED SILICON AND SILICON GERMANIUM FINS ON THE SAME WAFER - Various embodiments form strained and relaxed silicon and silicon germanium fins on a semiconductor wafer. In one embodiment a semiconductor wafer is formed. The semiconductor wafer comprises a substrate, a dielectric layer, and a strained silicon germanium (SiGe) layer. At least one region of the strained SiGe layer is transformed into a relaxed SiGe region. At least one strained SiGe fin is formed from a first strained SiGe region of the strained SiGe layer. At least one relaxed SiGe fin is formed from a first portion of the relaxed SiGe region. Relaxed silicon is epitaxially grown on a second strained SiGe region of the strained SiGe layer. Strained silicon is epitaxially grown on a second portion of the relaxed SiGe region. At least one relaxed silicon fin is formed from the relaxed silicon. At least one strained silicon fin is formed from the strained silicon. | 09-18-2014 |
20140264603 | PARTIALLY ISOLATED FIN-SHAPED FIELD EFFECT TRANSISTORS - A transistor device and a method for forming a fin-shaped field effect transistor (FinFET) device, with the channel portion of the fins on buried silicon oxide, while the source and drain portions of the fins on silicon. An example method includes receiving a wafer with a silicon layer electrically isolated from a silicon substrate by a buried oxide (BOX) layer. The BOX layer is in physical contact with the silicon layer and the silicon substrate. The method further comprises implanting a well in the silicon substrate and forming vertical sources and drains over the well between dummy gates. The vertical sources and drains extend through the BOX layer, fins, and a portion of the dummy gates. | 09-18-2014 |
20140264755 | STRAINED SILICON NFET AND SILICON GERMANIUM PFET ON SAME WAFER - Various embodiments form silicon and silicon germanium fins on a semiconductor wafer. In one embodiment a semiconductor wafer is obtained. The semiconductor wafer comprises a substrate, a dielectric layer, and a semiconductor layer including silicon germanium (SiGe). At least one SiGe fin is formed from at least a first SiGe region of the semiconductor layer in at least one PFET region of the semiconductor wafer. Strained silicon is epitaxially grown on at least a second SiGe region of the semiconductor layer. At least one strained silicon fin is formed from the strained silicon in at least one NFET region of the semiconductor wafer. | 09-18-2014 |
20140306274 | SELF-ALIGNED STRUCTURE FOR BULK FinFET - A FinFET structure which includes a bulk semiconductor substrate; semiconductor fins extending from the bulk semiconductor substrate, each of the semiconductor fins having a top portion and a bottom portion such that the bottom portion of the semiconductor fins is doped and the top portion of the semiconductor fins is undoped; a portion of the bulk semiconductor substrate directly underneath the plurality of semiconductor fins being doped to form an n+ or p+ well; and an oxide formed between the bottom portions of the fins. | 10-16-2014 |
20140306289 | SELF-ALIGNED STRUCTURE FOR BULK FinFET - A FinFET structure which includes a bulk semiconductor substrate; semiconductor fins extending from the bulk semiconductor substrate, each of the semiconductor fins having a top portion and a bottom portion such that the bottom portion of the semiconductor fins is doped and the top portion of the semiconductor fins is undoped; a portion of the bulk semiconductor substrate directly underneath the plurality of semiconductor fins being doped to form an n+ or p+ well; and an oxide formed between the bottom portions of the fins. Also disclosed is a method for forming a FinFET device. | 10-16-2014 |
20140312433 | CONTACT STRUCTURE EMPLOYING A SELF-ALIGNED GATE CAP - After formation of a replacement gate structure, a template dielectric layer employed to pattern the replacement gate structure is removed. After deposition of a dielectric liner, a first dielectric material layer is deposited by an anisotropic deposition and an isotropic etchback. A second dielectric material layer is deposited and planarized employing the first dielectric material portion as a stopping structure. The first dielectric material portion is removed selective to the second dielectric material layer, and is replaced with gate cap dielectric material portion including at least one dielectric material different from the materials of the dielectric material layers. A contact via hole extending to a source/drain region is formed employing the gate cap dielectric material portion as an etch stop structure. A contact via structure is spaced from the replacement gate structure at least by remaining portions of the gate cap dielectric material portion. | 10-23-2014 |
20140315379 | CONTACT STRUCTURE EMPLOYING A SELF-ALIGNED GATE CAP - After formation of a replacement gate structure, a template dielectric layer employed to pattern the replacement gate structure is removed. After deposition of a dielectric liner, a first dielectric material layer is deposited by an anisotropic deposition and an isotropic etchback. A second dielectric material layer is deposited and planarized employing the first dielectric material portion as a stopping structure. The first dielectric material portion is removed selective to the second dielectric material layer, and is replaced with gate cap dielectric material portion including at least one dielectric material different from the materials of the dielectric material layers. A contact via hole extending to a source/drain region is formed employing the gate cap dielectric material portion as an etch stop structure. A contact via structure is spaced from the replacement gate structure at least by remaining portions of the gate cap dielectric material portion. | 10-23-2014 |
20140339640 | FINFET WITH VERTICAL SILICIDE STRUCTURE - FinFETS and methods for making FinFETs with a vertical silicide structure. A method includes providing a substrate with a plurality of fins, forming a gate stack above the substrate wherein the gate stack has at least one sidewall and forming an off-set spacer adjacent the gate stack sidewall. The method also includes growing an epitaxial film which merges the fins to form an epi-merge layer, forming a field oxide layer adjacent to at least a portion of the off-set spacer and removing a portion of the field oxide layer to expose a portion of the epi-merge-layer. The method further includes removing at least part of the exposed portion of the epi-merge-layer to form an epi-merge sidewall and an epi-merge spacer region and forming a silicide within the epi-merge sidewall to form a silicide layer and two silicide sidewalls. | 11-20-2014 |
20140346640 | NON-LITHOGRAPHIC HOLE PATTERN FORMATION - A metal layer is deposited over a material layer. The metal layer includes an elemental metal that can be converted into a dielectric metal-containing compound by plasma oxidation or nitridation. A hard mask portion is formed over the metal layer. A plasma impermeable spacer is formed on at least one first sidewall of the hard mask portion, while at least one second sidewall of the hard mask portion is physically exposed. Plasma oxidation or nitridation is performed to convert physically exposed surfaces of the metal layer into the dielectric metal-containing compound. A sequence of a surface pull back of the hard mask portion, cavity etching, another surface pull back, and conversion of top surfaces into the dielectric metal-containing compound are repeated to form a hole pattern having a spacing that is not limited by lithographic minimum dimensions. | 11-27-2014 |
20140349088 | NON-LITHOGRAPHIC LINE PATTERN FORMATION - A metal layer is deposited over an underlying material layer. The metal layer includes an elemental metal that can be converted into a dielectric metal-containing compound by plasma oxidation and/or nitridation. A hard mask portion is formed over the metal layer. Plasma oxidation or nitridation is performed to convert physically exposed surfaces of the metal layer into the dielectric metal-containing compound. The sequence of a surface pull back of the hard mask portion, trench etching, another surface pull back, and conversion of top surfaces into the dielectric metal-containing compound are repeated to form a line pattern having a spacing that is not limited by lithographic minimum dimensions. | 11-27-2014 |
20140353735 | LOCALIZED FIN WIDTH SCALING USING A HYDROGEN ANNEAL - Transistors and methods for fabricating the same include forming one or more semiconductor fins on a substrate; covering source and drain regions of the one or more semiconductor fins with a protective layer; annealing uncovered channel portions of the one or more semiconductor fins in a gaseous environment to reduce fin width and round corners of the one or more semiconductor fins; and forming a dielectric layer and gate over the thinned fins. | 12-04-2014 |
20140367826 | MAKING AN EFUSE - A wafer chip and a method of designing the chip is disclosed. A first fuse is formed having a first critical dimension and a second fuse having a second critical dimension are formed in a layer of the chip. A voltage may be applied to burn out at least one of the first fuse and the second fuse. The first critical dimension of the first fuse may result from applying a first mask to the layer and applying light having a first property to the mask. The second critical dimension of the second fuse may result from applying a second mask to the layer and applying light having a second property to the mask. | 12-18-2014 |
20150021689 | ASYMMETRICAL REPLACEMENT METAL GATE FIELD EFFECT TRANSISTOR - An asymmetrical field effect transistor (FET) device includes a semiconductor substrate, a buried oxide layer disposed on the semiconductor substrate, an extended source region disposed on the buried oxide layer and a drain region disposed on the buried oxide layer. The asymmetrical FET device also includes a silicon on insulator region disposed between the extended source region and the drain region and a gate region disposed above the extended source region and the silicon on insulator region. | 01-22-2015 |
20150024558 | ASYMMETRICAL REPLACEMENT METAL GATE FIELD EFFECT TRANSISTOR - An asymmetrical field effect transistor (FET) device includes a semiconductor substrate, a buried oxide layer disposed on the semiconductor substrate, an extended source region disposed on the buried oxide layer and a drain region disposed on the buried oxide layer. The asymmetrical FET device also includes a silicon on insulator region disposed between the extended source region and the drain region and a gate region disposed above the extended source region and the silicon on insulator region. | 01-22-2015 |
20150041897 | ANCHORED STRESS-GENERATING ACTIVE SEMICONDUCTOR REGIONS FOR SEMICONDUCTOR-ON-INSULATOR FINFET - After formation of a gate structure and a gate spacer, portions of an insulator layer underlying a semiconductor fin are etched to physically expose semiconductor surfaces of an underlying semiconductor material layer from underneath a source region and a drain region. Each of the extended source region and the extended drain region includes an anchored single crystalline semiconductor material portion that is in epitaxial alignment to the single crystalline semiconductor structure of the underlying semiconductor material layer and laterally applying a stress to the semiconductor fin. Because each anchored single crystalline semiconductor material portion is in epitaxial alignment with the underlying semiconductor material layer, the channel of the fin field effect transistor is effectively stressed along the lengthwise direction of the semiconductor fin. | 02-12-2015 |
20150048429 | SIDEWALL IMAGE TRANSFER WITH A SPIN-ON HARDMASK - Semiconductor devices and sidewall image transfer methods with a spin on hardmask. Methods for forming fins include forming a trench through a stack of layers that includes a top and bottom insulator layer, and a layer to be patterned on a substrate; isotropically etching the top and bottom insulator layers; forming a hardmask material in the trench to the level of the bottom insulator layer; isotropically etching the top insulator layer; and etching the bottom insulator layer and the layer to be patterned down to the substrate to form fins from the layer to be patterned. | 02-19-2015 |
20150048430 | SIDEWALL IMAGE TRANSFER WITH A SPIN-ON HARDMASK - Semiconductor devices include a first and a second set of parallel fins, each set of fins having a same number of fins and a pitch between adjacent fins below a minimum pitch of an associated lithography process, where a spacing between the first and second set of fins is greater than the pitch between adjacent fins; a gate structure over the first and second sets of fins; a merged source region that connects the first and second sets of fins on a first side of the gate structure; and a merged drain region that connects the first and second sets of fins on a second side of the gate structure. | 02-19-2015 |
20150054077 | FINFET FORMED OVER DIELECTRIC - A method for semiconductor fabrication includes patterning one or more mandrels over a semiconductor substrate, the one or more mandrels having dielectric material formed therebetween. A semiconductor layer is formed over exposed portions of the one or more mandrels. A thermal oxidation is performed to diffuse elements from the semiconductor layer into an upper portion of the one or more mandrels and concurrently oxidize a lower portion of the one or more mandrels to form the one or more mandrels on the dielectric material. | 02-26-2015 |
20150054121 | FINFET FORMED OVER DIELECTRIC - A method for semiconductor fabrication includes patterning one or more mandrels over a semiconductor substrate, the one or more mandrels having dielectric material formed therebetween. A semiconductor layer is formed over exposed portions of the one or more mandrels. A thermal oxidation is performed to diffuse elements from the semiconductor layer into an upper portion of the one or more mandrels and concurrently oxidize a lower portion of the one or more mandrels to form the one or more mandrels on the dielectric material. | 02-26-2015 |
20150061015 | NON-MERGED EPITAXIALLY GROWN MOSFET DEVICES - Semiconductor devices having non-merged fin extensions and methods for forming the same. Methods for forming semiconductor devices include forming fins on a substrate; forming a dummy gate over the fins, leaving a source and drain region exposed; etching the fins below a surface level of a surrounding insulator layer; and epitaxially growing fin extensions from the etched fins. | 03-05-2015 |
20150064853 | INTEGRATED CIRCUIT INCLUDING DRAM AND SRAM/LOGIC - An integrated circuit comprising an N+ type layer, a buffer layer arranged on the N+ type layer; a P type region formed on with the buffer layer; an insulator layer overlying the N+ type layer, a silicon layer overlying the insulator layer, an embedded RAM FET formed in the silicon layer and connected with a conductive node of a trench capacitor that extends into the N+ type layer, the N+ type layer forming a plate electrode of the trench capacitor, a first contact through the silicon layer and the insulating layer and electrically connecting to the N+ type layer, a first logic RAM FET formed in the silicon layer above the P type region, the P type region functional as a P-type back gate of the first logic RAM FET, and a second contact through the silicon layer and the insulating layer and electrically connecting to the P type region. | 03-05-2015 |
20150076498 | TEST MACRO FOR USE WITH A MULTI-PATTERNING LITHOGRAPHY PROCESS - A method for forming an integrated circuit having a test macro using a multiple patterning lithography process (MPLP) is provided. The method includes forming an active area of the test macro having a first and second gate region during a first step of MPLP, and forming a first and second source/drain regions in the active area during a second step of the MPLP. The method also includes forming a first contact connected to the first gate region, a second contact connected to the second gate region, a third contact connected to the first source/drain region, and a forth contact connected to the source/drain region and determining if an overlay shift occurred between the first step and the second step of the step of the MPLP by testing for a short between one or more of the first contact, the second contact, the third contact, or the fourth contact. | 03-19-2015 |