Patent application number | Description | Published |
20080217742 | TAILORED BIPOLAR TRANSISTOR DOPING PROFILE FOR IMPROVED RELIABILITY - Bipolar transistor device structures that improve bipolar device reliability with little or no negative impact on device performance. In one embodiment, the bipolar device has a collector of first conductivity type material formed in a substrate, a base of a second conductivity type material including an extrinsic base layer and an intrinsic base layer, a raised emitter of a first conductivity type semiconductor material formed on the intrinsic base layer, and, a dielectric material layer separating the intrinsic base region and the raised emitter region, and, a thin “shunt” layer of dopant of second conductivity type material added to the region below the emitter dielectric layer. In a second embodiment, a selectively implanted collector (pedestal implant) is added to the vertical bipolar transistor device to enable a reduction in overall subcollector doping level to improve reliability without sacrificing device performance. These solutions add no additional masking steps and only one additional implantation step. | 09-11-2008 |
20080272399 | PIXEL SENSOR CELL FOR COLLECTING ELECTRONS AND HOLES - The present invention is a pixel sensor cell and method of making the same. The pixel sensor cell approximately doubles the available signal for a given quanta of light. The device of the present invention utilizes the holes produced by impinging photons in a pixel sensor cell circuit. A pixel sensor cell having reduced complexity includes an n-type collection well region formed beneath a surface of a substrate for collecting electrons generated by electromagnetic radiation impinging on the pixel sensor cell and a p-type collection well region formed beneath the surface of the substrate for collecting holes generated by the impinging photons. A circuit structure having a first input is coupled to the n-type collection well region and a second input is coupled to the p-type collection well region, wherein an output signal of the pixel sensor cell is the magnitude of the difference of a signal of the first input and a signal of the second input. | 11-06-2008 |
20080272400 | PIXEL SENSOR CELL FOR COLLECTING ELECTRONS AND HOLES - The present invention is a pixel sensor cell and method of making the same. The pixel sensor cell approximately doubles the available signal for a given quanta of light. The device of the present invention utilizes the holes produced by impinging photons in a pixel sensor cell circuit. A pixel sensor cell having reduced complexity includes an n-type collection well region formed beneath a surface of a substrate for collecting electrons generated by electromagnetic radiation impinging on the pixel sensor cell and a p-type collection well region formed beneath the surface of the substrate for collecting holes generated by the impinging photons. A circuit structure having a first input is coupled to the n-type collection well region and a second input is coupled to the p-type collection well region, wherein an output signal of the pixel sensor cell is the magnitude of the difference of a signal of the first input and a signal of the second input. | 11-06-2008 |
20080274578 | METHOD OF FORMING A PIXEL SENSOR CELL FOR COLLECTING ELECTRONS AND HOLES - The present invention is a pixel sensor cell and method of making the same. The pixel sensor cell approximately doubles the available signal for a given quanta of light. The device of the present invention utilizes the holes produced by impinging photons in a pixel sensor cell circuit. A pixel sensor cell having reduced complexity includes an n-type collection well region formed beneath a surface of a substrate for collecting electrons generated by electromagnetic radiation impinging on the pixel sensor cell and a p-type collection well region formed beneath the surface of the substrate for collecting holes generated by the impinging photons. A circuit structure having a first input is coupled to the n-type collection well region and a second input is coupled to the p-type collection well region, wherein an output signal of the pixel sensor cell is the magnitude of the difference of a signal of the first input and a signal of the second input. | 11-06-2008 |
20080296476 | PIXEL SENSOR CELL FOR COLLECTING ELECTIONS AND HOLES - The present invention is a pixel sensor cell and method of making the same. The pixel sensor cell approximately doubles the available signal for a given quanta of light. The device of the present invention utilizes the holes produced by impinging photons in a pixel sensor cell circuit. A pixel sensor cell having reduced complexity includes an n-type collection well region formed beneath a surface of a substrate for collecting electrons generated by electromagnetic radiation impinging on the pixel sensor cell and a p-type collection well region formed beneath the surface of the substrate for collecting holes generated by the impinging photons. A circuit structure having a first input is coupled to the n-type collection well region and a second input is coupled to the p-type collection well region, wherein an output signal of the pixel sensor cell is the magnitude of the difference of a signal of the first input and a signal of the second input. | 12-04-2008 |
20080315266 | JUNCTION FIELD EFFECT TRANSISTOR WITH A HYPERABRUPT JUNCTION - A junction field effect transistor (JFET) has a hyperabrupt junction layer that functions as a channel of a JFET. The hyperabrupt junction layer is formed by two dopant profiles of opposite types such that one dopant concentration profile has a peak concentration depth at a tail end of the other dopant profile. The voltage bias to the channel is provided by a body that is doped with the same type of dopants as the gate. This is in contrast with conventional JFETs that have a body that is doped with the opposite conductivity type as the gate. The body may be electrically decoupled from the substrate by another reverse bias junction formed either between the body and the substrate or between a buried conductor layer beneath the body and the substrate. The capability to form a thin hyperabrupt junction layer allows formation of a JFET in a semiconductor-on-insulator substrate. | 12-25-2008 |
20090035886 | PREDOPED TRANSFER GATE FOR A CMOS IMAGE SENSOR - A novel CMOS image sensor Active Pixel Sensor (APS) cell structure and method of manufacture. Particularly, a CMOS image sensor APS cell having a predoped transfer gate is formed that avoids the variations of V | 02-05-2009 |
20090250739 | Device Structures with a Hyper-Abrupt P-N Junction, Methods of Forming a Hyper-Abrupt P-N Junction, and Design Structures for an Integrated Circuit - Device structures with hyper-abrupt p-n junctions, methods of forming hyper-abrupt p-n junctions, and design structures for an integrated circuit containing devices structures with hyper-abrupt p-n junctions. The hyper-abrupt p-n junction is defined in a SOI substrate by implanting a portion of a device layer to have one conductivity type and then implanting a portion of this doped region to have an opposite conductivity type. The counterdoping defines the hyper-abrupt p-n junction. A gate structure carried on a top surface of the device layer operates as a hard mask during the ion implantations to assist in defining a lateral boundary for the hyper-abrupt-n junction. | 10-08-2009 |
20090256204 | SOI TRANSISTOR WITH MERGED LATERAL BIPOLAR TRANSISTOR - A semiconductor-on-insulator transistor device includes a source region, a drain region, a body region, and a source-side lateral bipolar transistor. The source region has a first conductivity type. The body region has a second conductivity type and is positioned between the source region and the drain region. The source-side lateral bipolar transistor includes a base, a collector, and an emitter. A silicide region connects the base to the collector. The emitter is the body region. The collector has the second conductivity type, and the base is the source region and is positioned between the emitter and the collector. | 10-15-2009 |
20090294850 | METHOD TO TAILOR LOCATION OF PEAK ELECTRIC FIELD DIRECTLY UNDERNEATH AN EXTENSION SPACER FOR ENHANCED PROGRAMMABILITY OF A PROMPT-SHIFT DEVICE - The invention provides a method to enhance the programmability of a prompt-shift device, which reduces the programming time to sub-millisecond times, by altering the extension and halo implants, instead of simply omitting the same from one side of the device as is the case in the prior art prompt-shift devices. The invention includes an embodiment in which no additional masks are employed, or one additional mask is employed. The altered extension implant is performed at a reduced ion dose as compared to a conventional extension implant process, while the altered halo implant is performed at a higher ion dose than a conventional halo implant. The altered halo/extension implant shifts the peak of the electrical field to under an extension dielectric spacer. | 12-03-2009 |
20100117237 | Silicided Trench Contact to Buried Conductive Layer - A trench contact silicide is formed on an inner wall of a contact trench that reaches to a buried conductive layer in a semiconductor substrate to reduce parasitic resistance of a reachthrough structure. The trench contact silicide is formed at the bottom, on the sidewalls of the trench, and on a portion of the top surface of the semiconductor substrate. The trench is subsequently filled with a middle-of-line (MOL) dielectric. A contact via may be formed on the trench contact silicide. The trench contact silicide may be formed through a single silicidation reaction with a metal layer or through multiple silicidation reactions with multiple metal layers. | 05-13-2010 |
20100230753 | LATERAL HYPERABRUPT JUNCTION VARACTOR DIODE IN AN SOI SUBSTRATE - A varactor diode includes a portion of a top semiconductor layer of a semiconductor-on-insulator (SOI) substrate and a gate electrode located thereupon. A first electrode having a doping of a first conductivity type laterally abuts a doped semiconductor region having the first conductivity type, which laterally abuts a second electrode having a doping of a second conductivity type, which is the opposite of the first conductivity type. A hyperabrupt junction is formed between the second doped semiconductor region and the second electrode. The gate electrode controls the depletion of the first and second doped semiconductor regions, thereby varying the capacitance of the varactor diode. A design structure for the varactor diode is also provided. | 09-16-2010 |
20100248432 | METHODS OF FORMING A HYPER-ABRUPT P-N JUNCTION AND DESIGN STRUCTURES FOR AN INTEGRATED CIRCUIT - Methods of forming hyper-abrupt p-n junctions and design structures for an integrated circuit containing devices structures with hyper-abrupt p-n junctions. The hyper-abrupt p-n junction is defined in a SOI substrate by implanting a portion of a device layer to have one conductivity type and then implanting a portion of this doped region to have an opposite conductivity type. The counterdoping defines the hyper-abrupt p-n junction. A gate structure carried on a top surface of the device layer operates as a hard mask during the ion implantations to assist in defining a lateral boundary for the hyper-abrupt p-n junction. | 09-30-2010 |
20100279483 | LATERAL PASSIVE DEVICE HAVING DUAL ANNULAR ELECTRODES - A lateral passive device is disclosed including a dual annular electrode. The annular electrodes form an anode and a cathode. The annular electrodes allow anode and cathode series resistances to be optimized to the lowest values at a fixed device area. In addition, the parasitic capacitance to a bottom plate (substrate) is greatly reduced. In one embodiment, a device includes a first annular electrode surrounding a second annular electrode formed on a substrate, and the second annular electrode surrounds an insulator region. A related method is also disclosed. | 11-04-2010 |
20100297825 | Passive Components in the Back End of Integrated Circuits - Passive components are formed in the back end by using the same deposition process and materials as in the rest of the back end. Resistors are formed by connecting in series individual structures on the nth, (n+1)th, etc levels of the back end. Capacitors are formed by constructing a set of vertical capacitor plates from a plurality of levels in the back end, the plates being formed by connecting electrodes on two or more levels of the back end by vertical connection members. | 11-25-2010 |
20110049582 | ASYMMETRIC SOURCE AND DRAIN STRESSOR REGIONS - A method forms a structure has a substrate having at least one semiconductor channel region, a gate dielectric on the upper surface of the substrate over the semiconductor channel region, and a gate conductor on the gate dielectric. Asymmetric sidewall spacers are located on the sidewalls of the gate conductor and asymmetric source and drain regions are located within the substrate adjacent the semiconductor channel region. One source/drain region is positioned closer to the midpoint of the gate conductor than is the other source/drain region. The source and drain regions comprise a material that induces physical stress upon the semiconductor channel region. | 03-03-2011 |
20110143494 | SCHOTTKY BARRIER DIODES FOR MILLIMETER WAVE SiGe BICMOS APPLICATIONS - A method for forming a Schottky barrier diode on a SiGe BiCMOS wafer, including forming a structure which provides a cutoff frequency (F | 06-16-2011 |
20110183486 | TRANSISTOR HAVING V-SHAPED EMBEDDED STRESSOR - A semiconductor device and a method of making the device are provided. The method can include forming a gate conductor overlying a major surface of a monocrystalline semiconductor region and forming first spacers on exposed walls of the gate conductor. Using the gate conductor and the first spacers as a mask, at least extension regions are implanted in the semiconductor region and dummy spacers are formed extending outward from the first spacers. Using the dummy spacers as a mask, the semiconductor region is etched to form recesses having at least substantially straight walls extending downward from the major surface to a bottom surface, such that a substantial angle is defined between the bottom surface and the walls. Subsequently, the process is continued by epitaxially growing regions of stressed monocrystalline semiconductor material within the recesses. Then the dummy spacers are removed and the transistor can be completed by forming source/drain regions of the transistor that are at least partially disposed in the stressed semiconductor material regions. | 07-28-2011 |
20110212587 | ASYMMETRIC SOURCE AND DRAIN STRESSOR REGIONS - A method forms a structure has a substrate having at least one semiconductor channel region, a gate dielectric on the upper surface of the substrate over the semiconductor channel region, and a gate conductor on the gate dielectric. Asymmetric sidewall spacers are located on the sidewalls of the gate conductor and asymmetric source and drain regions are located within the substrate adjacent the semiconductor channel region. One source/drain region is positioned closer to the midpoint of the gate conductor than is the other source/drain region. The source and drain regions comprise a material that induces physical stress upon the semiconductor channel region. | 09-01-2011 |
20110291169 | REDUCED CORNER LEAKAGE IN SOI STRUCTURE AND METHOD - A structural alternative to retro doping to reduce transistor leakage is provided by providing a liner in a trench, undercutting a conduction channel region in an active semiconductor layer, etching a side, corner and/or bottom of the conduction channel where the undercut exposes semiconductor material in the active layer and replacing the removed portion of the conduction channel with insulator. This shaping of the conduction channel increases the distance to adjacent circuit elements which, if charged, could otherwise induce a voltage and cause a change in back-channel threshold in regions of the conduction channel and narrows and reduces cross-sectional area of the channel where the conduction in the channel is not well-controlled; both of which effects significantly reduce leakage of the transistor. | 12-01-2011 |
20110316044 | DELTA MONOLAYER DOPANTS EPITAXY FOR EMBEDDED SOURCE/DRAIN SILICIDE - Semiconductor structures are disclosed that have embedded stressor elements therein. The disclosed structures include at least one FET gate stack located on an upper surface of a semiconductor substrate. The at least one FET gate stack includes source and drain extension regions located within the semiconductor substrate at a footprint of the at least one FET gate stack. A device channel is also present between the source and drain extension regions and beneath the at least one gate stack. The structure further includes embedded stressor elements located on opposite sides of the at least one FET gate stack and within the semiconductor substrate. Each of the embedded stressor elements includes, from bottom to top, a first layer of a first epitaxy doped semiconductor material having a lattice constant that is different from a lattice constant of the semiconductor substrate and imparts a strain in the device channel, a second layer of a second epitaxy doped semiconductor material located atop the first layer, and a delta monolayer of dopant located on an upper surface of the second layer. The structure further includes a metal semiconductor alloy contact located directly on an upper surface of the delta monolayer. | 12-29-2011 |
20110316061 | STRUCTURE AND METHOD TO CONTROL BOTTOM CORNER THRESHOLD IN AN SOI DEVICE - Semiconductor structures and methods to control bottom corner threshold in a silicon-on-insulator (SOI) device. A method includes doping a corner region of a semiconductor-on-insulator (SOI) island. The doping includes tailoring a localized doping of the corner region to reduce capacitive coupling of the SOI island with an adjacent structure. | 12-29-2011 |
20120086077 | FET STRUCTURES WITH TRENCH IMPLANTATION TO IMPROVE BACK CHANNEL LEAKAGE AND BODY RESISTANCE - An FET structure on a semiconductor substrate which includes forming recesses for a source and a drain of the gate structure on a semiconductor substrate, halo implanting regions through the bottom of the source and drain recesses, the halo implanted regions being underneath the gate stack, implanting junction butting at the bottom of the source and drain recesses, and filling the source and drain recesses with a doped epitaxial material. In exemplary embodiments, the semiconductor substrate is a semiconductor on insulator substrate including a semiconductor layer on a buried oxide layer. In exemplary embodiments, the junction butting and halo implanted regions are in contact with the buried oxide layer. In other exemplary embodiments, there is no junction butting. In exemplary embodiments, halo implants implanted to a lower part of the FET body underneath the gate structure provide higher doping level in lower part of the FET body to reduce body resistance, without interfering with FET threshold voltage. | 04-12-2012 |
20120112206 | ASYMMETRIC HETERO-STRUCTURE FET AND METHOD OF MANUFACTURE - An asymmetric hetero-structure FET and method of manufacture is provided. The structure includes a semiconductor substrate and an epitaxially grown semiconductor layer on the semiconductor substrate. The epitaxially grown semiconductor layer includes an alloy having a band structure and thickness that confines inversion carriers in a channel region, and a thicker portion extending deeper into the semiconductor structure at a doped edge to avoid confinement of the inversion carriers at the doped edge. | 05-10-2012 |
20120112280 | BUTTED SOI JUNCTION ISOLATION STRUCTURES AND DEVICES AND METHOD OF FABRICATION - A structure, a FET, a method of making the structure and of making the FET. The structure including: a silicon layer on a buried oxide (BOX) layer of a silicon-on-insulator substrate; a trench in the silicon layer extending from a top surface of the silicon layer into the silicon layer, the trench not extending to the BOX layer, a doped region in the silicon layer between and abutting the BOX layer and a bottom of the trench, the first doped region doped to a first dopant concentration; a first epitaxial layer, doped to a second dopant concentration, in a bottom of the trench; a second epitaxial layer, doped to a third dopant concentration, on the first epitaxial layer in the trench; and wherein the third dopant concentration is greater than the first and second dopant concentrations and the first dopant concentration is greater than the second dopant concentration. | 05-10-2012 |
20120119294 | CREATING ANISOTROPICALLY DIFFUSED JUNCTIONS IN FIELD EFFECT TRANSISTOR DEVICES - A method of forming a transistor device includes implanting a diffusion inhibiting species in a semiconductor-on-insulator substrate comprising a bulk substrate, a buried insulator layer, and a semiconductor-on-insulator layer, the semiconductor-on-insulator substrate having one or more gate structures formed thereon such that the diffusion inhibiting species is disposed in portions of the semiconductor-on-insulator layer corresponding to a channel region, and disposed in portions of the buried insulator layer corresponding to source and drain regions. A transistor dopant species is introduced in the source and drain regions. An anneal is performed so as to diffuse the transistor dopant species in a substantially vertical direction while substantially preventing lateral diffusion of the transistor dopant species into the channel region. | 05-17-2012 |
20120119302 | Trench Silicide Contact With Low Interface Resistance - An electrical structure is provided that includes a dielectric layer present on a semiconductor substrate and a via opening present through the dielectric layer. | 05-17-2012 |
20120139015 | METAL SEMICONDUCTOR ALLOY CONTACT WITH LOW RESISTANCE - A method of forming a semiconductor device is provided that includes forming a gate structure on a channel portion of a semiconductor substrate, forming an interlevel dielectric layer over the gate structure, and forming a opening through the interlevel dielectric layer to an exposed surface of the semiconductor substrate containing at least one of the source region and the drain region. A metal semiconductor alloy contact is formed on the exposed surface of the semiconductor substrate. At least one dielectric sidewall spacer is formed on sidewalls of the opening. An interconnect is formed within the opening in direct contact with the metal semiconductor alloy contact. | 06-07-2012 |
20120181549 | STRESSED CHANNEL FET WITH SOURCE/DRAIN BUFFERS - A method for forming a stressed channel field effect transistor (FET) with source/drain buffers includes etching cavities in a substrate on either side of a gate stack located on the substrate; depositing source/drain buffer material in the cavities; etching the source/drain buffer material to form vertical source/drain buffers adjacent to a channel region of the FET; and depositing source/drain stressor material in the cavities adjacent to and over the vertical source/drain buffers. | 07-19-2012 |
20120181627 | METHOD TO TAILOR LOCATION OF PEAK ELECTRIC FIELD DIRECTLY UNDERNEATH AN EXTENSION SPACER FOR ENHANCED PROGRAMMABILITY OF A PROMPT-SHIFT DEVICE - A prompt-shift device having reduced programming time in the sub-millisecond range is provided. The prompt-shift device includes an altered extension region located within said semiconductor substrate and on at least one side of the patterned gate region, and an altered halo region located within the semiconductor substrate and on at least one side of the patterned gate region. The altered extension region has an extension ion dopant concentration of less than about 1E20 atoms/cm | 07-19-2012 |
20120181628 | METHOD TO TAILOR LOCATION OF PEAK ELECTRIC FIELD DIRECTLY UNDERNEATH AN EXTENSION SPACER FOR ENHANCED PROGRAMMABILITY OF A PROMPT-SHIFT DEVICE - A prompt-shift device having reduced programming time in the sub-millisecond range is provided. The prompt-shift device includes an altered extension region located within said semiconductor substrate and on at least one side of the patterned gate region, and an altered halo region located within the semiconductor substrate and on at least one side of the patterned gate region. The altered extension region has an extension ion dopant concentration of less than about 1E20 atoms/cm | 07-19-2012 |
20120187490 | FET STRUCTURES WITH TRENCH IMPLANTATION TO IMPROVE BACK CHANNEL LEAKAGE AND BODY RESISTANCE - A field effect transistor (FET) structure on a semiconductor substrate which includes a gate structure having a spacer on a semiconductor substrate; an extension implant underneath the gate structure; a recessed source and a recessed drain filled with a doped epitaxial material; halo implanted regions adjacent a bottom of the recessed source and drain and being underneath the gate stack. In an exemplary embodiment, there is implanted junction butting underneath the bottom of each of the recessed source and drain, the junction butting being separate and distinct from the halo implanted regions. In another exemplary embodiment, the doped epitaxial material is graded from a lower dopant concentration at a side of the recessed source and drain to a higher dopant concentration at a center of the recessed source and drain. In a further exemplary embodiment, the semiconductor substrate is a semiconductor on insulator substrate. | 07-26-2012 |
20120199907 | LATERAL HYPERABRUPT JUNCTION VARACTOR DIODE IN AN SOI SUBSTRATE - A varactor diode includes a portion of a top semiconductor layer of a semiconductor-on-insulator (SOI) substrate and a gate electrode located thereupon. A first electrode having a doping of a first conductivity type laterally abuts a doped semiconductor region having the first conductivity type, which laterally abuts a second electrode having a doping of a second conductivity type, which is the opposite of the first conductivity type. A hyperabrupt junction is formed between the second doped semiconductor region and the second electrode. The gate electrode controls the depletion of the first and second doped semiconductor regions, thereby varying the capacitance of the varactor diode. A design structure for the varactor diode is also provided. | 08-09-2012 |
20120205716 | Epitaxially Grown Extension Regions for Scaled CMOS Devices - Epitaxially grown extension regions are disclosed for scaled CMOS devices. Semiconductor devices are provided that comprise a field effect transistor (FET) structure having a gate stack on a silicon substrate, wherein the field effect transistor structure comprises at least a channel layer formed below the gate stack. One or more etched extension regions containing an epitaxially grown dopant are provided in the channel layer. | 08-16-2012 |
20120326233 | METHOD TO REDUCE THRESHOLD VOLTAGE VARIABILITY WITH THROUGH GATE WELL IMPLANT - The present disclosure provides a semiconductor device that may include a substrate including a semiconductor layer overlying an insulating layer. A gate structure that is present on a channel portion of the semiconductor layer. A first dopant region is present in the channel portion of the semiconductor layer, in which the peak concentration of the first dopant region is present within the lower portion of the gate conductor and the upper portion of the semiconductor layer. A second dopant region is present in the channel portion of the semiconductor layer, in which the peak concentration of the second dopant region is present within the lower portion of the semiconductor layer. | 12-27-2012 |
20120326752 | DESIGN METHOD AND STRUCTURE FOR A TRANSISTOR HAVING A RELATIVELY LARGE THRESHOLD VOLTAGE VARIATION RANGE AND FOR A RANDOM NUMBER GENERATOR INCORPORATING MULTIPLE ESSENTIALLY IDENTICAL TRANSISTORS HAVING SUCH A LARGE THRESHOLD VOLTAGE VARIATION RANGE - Disclosed are a design method and structure for a transistor having a relatively large threshold voltage (Vt) variation range due to exacerbated random dopant fluctuation (RDF). Exacerbated RDF and, thereby a relatively large Vt variation range, is achieved through the use of complementary doping in one or more transistor components and/or through lateral dopant non-uniformity between the channel region and any halo regions. Also disclosed are a design method and structure for a random number generator, which incorporates multiple pairs of essentially identical transistors having such a large Vt variation and which relies on Vt mismatch in pairs of those the transistors to generate a multi-bit output (e.g., a unique identifier for a chip or a secret key). By widening the Vt variation range of the transistors in the random number generator, detecting Vt mismatch between transistors becomes more likely and the resulting multi-bit output will be more stable. | 12-27-2012 |
20130015580 | REPLACEMENT METAL GATE STRUCTURE AND METHODS OF MANUFACTUREAANM JAIN; SAMEER HAACI BeaconAAST NYAACO USAAGP JAIN; SAMEER H Beacon NY USAANM Johnson; Jeffrey B.AACI Essex JunctionAAST VTAACO USAAGP Johnson; Jeffrey B. Essex Junction VT USAANM Li; YingAACI NewburghAAST NYAACO USAAGP Li; Ying Newburgh NY USAANM Nayfeh; Hasan M.AACI PoughkeepsieAAST NYAACO USAAGP Nayfeh; Hasan M. Poughkeepsie NY USAANM Ramachandran; RavikumarAACI PleasantvilleAAST NYAACO USAAGP Ramachandran; Ravikumar Pleasantville NY US - A replacement metal gate structure and methods of manufacturing the same is provided. The method includes forming at least one trench structure and forming a liner of high-k dielectric material in the at least one trench structure. The method further includes adjusting a height of the liner of high-k dielectric material. The method further includes forming at least one workfunction metal over the liner, and forming a metal gate structure in the at least one trench structure, over the at least one workfunction metal and the liner of high-k dielectric material. | 01-17-2013 |
20130140636 | STRESSED CHANNEL FET WITH SOURCE/DRAIN BUFFERS - A stressed channel field effect transistor (FET) includes a substrate; a gate stack located on the substrate; a channel region located in the substrate under the gate stack; source/drain stressor material located in cavities in the substrate on either side of the channel region; and vertical source/drain buffers located in the cavities in the substrate between the source/drain stressor material and the substrate, wherein the source/drain stressor material abuts the channel region above the source/drain buffers. | 06-06-2013 |
20130171795 | TRENCH SILICIDE CONTACT WITH LOW INTERFACE RESISTANCE - An electrical structure is provided that includes a dielectric layer present on a semiconductor substrate and a via opening present through the dielectric layer. | 07-04-2013 |
20130187198 | HETEROJUNCTION BIPOLAR TRANSISTOR WITH REDUCED SUB-COLLECTOR LENGTH, METHOD OF MANUFACTURE AND DESIGN STRUCTURE - A heterojunction bipolar transistor (HBT) structure, method of manufacturing the same and design structure thereof are provided. The HBT structure includes a semiconductor substrate having a sub-collector region therein. The HBT structure further includes a collector region overlying a portion of the sub-collector region. The HBT structure further includes an intrinsic base layer overlying at least a portion of the collector region. The HBT structure further includes an extrinsic base layer adjacent to and electrically connected to the intrinsic base layer. The HBT structure further includes an isolation region extending vertically between the extrinsic base layer and the sub-collector region. The HBT structure further includes an emitter overlying a portion of the intrinsic base layer. The HBT structure further includes a collector contact electrically connected to the sub-collector region. The collector contact advantageously extends through at least a portion of the extrinsic base layer. | 07-25-2013 |
20130189818 | TRENCH ISOLATION AND METHOD OF FABRICATING TRENCH ISOLATION - Trench isolation structure and method of forming trench isolation structures. The structures includes a trench in a silicon region of a substrate, the trench extending from a top surface of the substrate into the silicon region; an ion implantation stopping layer over sidewalls of the trench; a dielectric fill material filling remaining space in the trench, the dielectric fill material not including any materials found in the stopping layer; an N-type dopant species in a first region of the silicon region on a first side of the trench; the N-type dopant species in a first region of the dielectric material adjacent to the first side of the trench; a P-type dopant species in a second region of the silicon region on a second side of the trench; and the P-type dopant species in a second region of the dielectric material adjacent to the second side of the trench. | 07-25-2013 |
20130189826 | Reduced Corner Leakage in SOI Structure and Method - A structural alternative to retro doping to reduce transistor leakage is provided by providing a liner in a trench, undercutting a conduction channel region in an active semiconductor layer, etching a side, corner and/or bottom of the conduction channel where the undercut exposes semiconductor material in the active layer and replacing the removed portion of the conduction channel with insulator. This shaping of the conduction channel increases the distance to adjacent circuit elements which, if charged, could otherwise induce a voltage and cause a change in back-channel threshold in regions of the conduction channel and narrows and reduces cross-sectional area of the channel where the conduction in the channel is not well-controlled; both of which effects significantly reduce leakage of the transistor. | 07-25-2013 |
20130285211 | DEVICE STRUCTURES COMPATIBLE WITH FIN-TYPE FIELD-EFFECT TRANSISTOR TECHNOLOGIES - Device structures, design structures, and fabrication methods for fin-type field-effect transistor integrated circuit technologies. First and second fins, which constitute electrodes of the device structure, are each comprised of a first semiconductor material. The second fin is formed adjacent to the first fin to define a gap separating the first and second fins. Positioned in the gap is a layer comprised of a second semiconductor material. | 10-31-2013 |
20130295742 | METHOD TO TAILOR LOCATION OF PEAK ELECTRIC FIELD DIRECTLY UNDERNEATH AN EXTENSION SPACER FOR ENHANCED PROGRAMMABILITY OF A PROMPT-SHIFT DEVICE - A method to enhance the programmability of a prompt-shift device is provided, which reduces the programming time to sub-millisecond times, by altering the extension and halo implants, instead of simply omitting the same from one side of the device as is the case in the prior art prompt-shift devices. In one embodiment, no additional masks are employed. The altered extension implant is performed at a reduced ion dose as compared to a conventional extension implant process, while the altered halo implant is performed at a higher ion dose than a conventional halo implant. The altered halo/extension implant shifts the peak of the electrical field to under an extension dielectric spacer. | 11-07-2013 |
20140017862 | METAL SEMICONDUCTOR ALLOY CONTACT WITH LOW RESISTANCE - A method of forming a semiconductor device is provided that includes forming a gate structure on a channel portion of a semiconductor substrate, forming an interlevel dielectric layer over the gate structure, and forming a opening through the interlevel dielectric layer to an exposed surface of the semiconductor substrate containing at least one of the source region and the drain region. A metal semiconductor alloy contact is formed on the exposed surface of the semiconductor substrate. At least one dielectric sidewall spacer is formed on sidewalls of the opening. An interconnect is formed within the opening in direct contact with the metal semiconductor alloy contact. | 01-16-2014 |
20140042541 | CREATING ANISOTROPICALLY DIFFUSED JUNCTIONS IN FIELD EFFECT TRANSISTOR DEVICES - A method of forming a transistor device includes implanting a diffusion inhibiting species in a semiconductor-on-insulator substrate comprising a bulk substrate, a buried insulator layer, and a semiconductor-on-insulator layer, the semiconductor-on-insulator substrate having one or more gate structures formed thereon such that the diffusion inhibiting species is disposed in portions of the semiconductor-on-insulator layer corresponding to a channel region, and disposed in portions of the buried insulator layer corresponding to source and drain regions. A transistor dopant species is introduced in the source and drain regions. An anneal is performed so as to diffuse the transistor dopant species in a substantially vertical direction while substantially preventing lateral diffusion of the transistor dopant species into the channel region. | 02-13-2014 |
20140151750 | HETEROJUNCTION BIPOLAR TRANSISTOR - Structures and methods of making a heterojunction bipolar transistor (HBT) device that include: an n-type collector region disposed within a crystalline silicon layer; a p-type intrinsic base comprising a boron-doped silicon germanium crystal that is disposed on a top surface of an underlying crystalline Si layer, which is bounded by shallow trench isolators (STIs), and that forms angled facets on interfaces of the underlying crystalline Si layer with the shallow trench isolators (STIs); a Ge-rich, crystalline silicon germanium layer that is disposed on the angled facets and not on a top surface of the p-type intrinsic base; and an n-type crystalline emitter disposed on a top surface and not on the angled lateral facets of the p-type intrinsic base. | 06-05-2014 |
20140175550 | DEVICE STRUCTURES COMPATIBLE WITH FIN-TYPE FIELD-EFFECT TRANSISTOR TECHNOLOGIES - Device structures, design structures, and fabrication methods for fin-type field-effect transistor integrated circuit technologies. First and second fins, which constitute electrodes of the device structure, are each comprised of a first semiconductor material. The second fin is formed adjacent to the first fin to define a gap separating the first and second fins. Positioned in the gap is a layer comprised of a second semiconductor material. | 06-26-2014 |
20140203359 | BUTTED SOI JUNCTION ISOLATION STRUCTURES AND DEVICES AND METHOD OF FABRICATION - A structure, a FET, a method of making the structure and of making the FET. The structure including: a silicon layer on a buried oxide (BOX) layer of a silicon-on-insulator substrate; a trench in the silicon layer extending from a top surface of the silicon layer into the silicon layer, the trench not extending to the BOX layer, a doped region in the silicon layer between and abutting the BOX layer and a bottom of the trench, the first doped region doped to a first dopant concentration; a first epitaxial layer, doped to a second dopant concentration, in a bottom of the trench; a second epitaxial layer, doped to a third dopant concentration, on the first epitaxial layer in the trench; and wherein the third dopant concentration is greater than the first and second dopant concentrations and the first dopant concentration is greater than the second dopant concentration. | 07-24-2014 |
20140239498 | SILICIDED TRENCH CONTACT TO BURIED CONDUCTIVE LAYER - A trench contact silicide is formed on an inner wall of a contact trench that reaches to a buried conductive layer in a semiconductor substrate to reduce parasitic resistance of a reachthrough structure. The trench contact silicide is formed at the bottom, on the sidewalls of the trench, and on a portion of the top surface of the semiconductor substrate. The trench is subsequently filled with a middle-of-line (MOL) dielectric. A contact via may be formed on the trench contact silicide. The trench contact silicide may be formed through a single silicidation reaction with a metal layer or through multiple silicidation reactions with multiple metal layers. | 08-28-2014 |
20150014771 | DUAL L-SHAPED DRIFT REGIONS IN AN LDMOS DEVICE AND METHOD OF MAKING THE SAME - A semiconductor device comprising dual L-shaped drift regions in a lateral diffused metal oxide semiconductor (LDMOS) and a method of making the same. The LDMOS in the semiconductor device comprises a trench isolation region or a deep trench encapsulated by a liner, a first L-shaped drift region, and a second L-shaped drift region. The LDMOS comprising the dual L-shape drift regions is integrated with silicon-germanium (SiGe) technology. The LDMOS comprising the dual L-shape drift regions furnishes a much higher voltage drop in a lateral direction within a much shorter distance from a drain region than the traditional LDMOS does. | 01-15-2015 |