| Patent application number | Description | Published |
|---|
| 20080213964 | FIELD EFFECT TRANSISTOR WITH THIN GATE ELECTRODE AND METHOD OF FABRICATING SAME - A field effect transistor and a method of fabricating the field effect transistor. The field effect transistor includes: a silicon body, a perimeter of the silicon body abutting a dielectric isolation; a source and a drain formed in the body and on opposite sides of a channel formed in the body; and a gate dielectric layer between the body and an electrically conductive gate electrode, a bottom surface of the gate dielectric layer in direct physical contact with a top surface of the body and a bottom surface the gate electrode in direct physical contact with a top surface of the gate dielectric layer, the gate electrode having a first region having a first thickness and a second region having a second thickness, the first region extending along the top surface of the gate dielectric layer over the channel region, the second thickness greater than the first thickness. | 09-04-2008 |
| 20080217707 | TRANSISTOR HAVING GATE AND BODY IN DIRECT SELF-ALIGNED CONTACT AND RELATED METHODS - A transistor having a directly contacting gate and body and related methods are disclosed. In one embodiment, the transistor includes a gate; a body; and a dielectric layer extending over the body to insulate the gate from the body along an entire surface of the body except along a portion of at least a sidewall of the body, wherein the gate is in direct contact with the body at the portion. One method may include providing the body; forming a sacrificial layer that contacts at least a portion of a sidewall of the body; forming a dielectric layer about the body except at the at least a portion; removing the sacrificial layer; and forming the gate about the body such that the gate contacts the at least a portion of the sidewall of the body. | 09-11-2008 |
| 20080268588 | RECESSED GATE CHANNEL WITH LOW Vt CORNER - A recessed gate FET device includes a substrate having an upper and lower portions, the lower portion having a reduced concentration of dopant material than the upper portion; a trench-type gate electrode defining a surrounding channel region and having a gate dielectric material layer lining and including a conductive material having a top surface recessed to reduce overlap capacitance with respect to the source and drain diffusion regions formed at an upper substrate surface at either side of the gate electrode. There is optionally formed halo implants at either side of and abutting the gate electrode, each halo implants extending below the source and drain diffusions into the channel region. Additionally, highly doped source and drain extension regions are formed that provide a low resistance path from the source and drain diffusion regions to the channel region. The recessed gate FET device suppresses short channel effects and exhibits improved threshold voltage (Vt) characteristics at corners of the trench bottom. | 10-30-2008 |
| 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 |
| 20090020806 | ASYMMETRIC FIELD EFFECT TRANSISTOR STRUCTURE AND METHOD - Disclosed are embodiments of an asymmetric field effect transistor structure and a method of forming the structure in which both series resistance in the source region (R | 01-22-2009 |
| 20090020819 | FIN-TYPE FIELD EFFECT TRANSISTOR STRUCTURE WITH MERGED SOURCE/DRAIN SILICIDE AND METHOD OF FORMING THE STRUCTURE - Disclosed herein are embodiments of a multiple fin fin-type field effect transistor (i.e., a multiple fin dual-gate or tri-gate field effect transistor) in which the multiple fins are partially or completely merged by a highly conductive material (e.g., a metal silicide). Merging the fins in this manner allow series resistance to be minimized with little, if any, increase in the parasitic capacitance between the gate and source/drain regions. Merging the semiconductor fins in this manner also allows each of the source/drain regions to be contacted by a single contact via as well as more flexible placement of that contact via. | 01-22-2009 |
| 20090020830 | ASYMMETRIC FIELD EFFECT TRANSISTOR STRUCTURE AND METHOD - Disclosed are embodiments for a design structure of an asymmetric field effect transistor structure and a method of forming the structure in which both series resistance in the source region (R | 01-22-2009 |
| 20090050975 | Active Silicon Interconnect in Merged Finfet Process - Dummy fins are positioned between source and drain regions of adjacent complementary multi-gate fin-type field effect transistors (MUGFETS) prior to selective silicon growth and silicidation. The dummy fins are parallel to, have the same thickness as, and have a smaller length than the fins within the MUGFETs. Further, the source regions of a first MUGFET, the drain regions of a second MUGFET, and the dummy fins are positioned along a single straight linear path, such that the single straight linear path crosses all of the source regions of the first MUGFET, the drain regions of the second MUGFET, and the dummy fins. Because the dummy fins comprise silicon, the dummy fins enhance the ability to selectively grow silicon within the source/drain connection silicide region. Then, after the source/drain connection silicide region is silicided, a consistently formed and reliable electrical connection is made between the source regions of one transistor and the drain regions of the other transistor to properly connect a CMOS structure. | 02-26-2009 |
| 20090057781 | MUGFET WITH OPTIMIZED FILL STRUCTURES - A semiconductor structure includes active multi-gate fin-type field effect transistor (MUGFET) structures and inactive MUGFET fill structures between the active MUGFET structures. The active MUGFET structures comprise transistors that change conductivity depending upon voltages within gates of the active MUGFET structures. Conversely, the inactive MUGFET fill structures comprise passive devices that do not change conductivity irrespective of voltages within gates of the inactive MUGFET fill structures. The gates of the active MUGFET structures are parallel to the gates of the inactive MUGFET fill structures, and the fins of the active MUGFET structures are the same size as the fins of the inactive MUGFET fill structures. The active MUGFET structures have the same pitch as the gates of the inactive MUGFET fill structures. The gates of the active MUGFET structures comprise active doping agents, but the inactive MUGFET fill structures do not contain the active doping agents. | 03-05-2009 |
| 20090096026 | METHOD OF FABRICATING HIGH VOLTAGE FULLY DEPLETED SOI TRANSISTOR AND STRUCTURE THEREOF - A method of fabricating a high voltage fully depleted silicon-on-insulator (FD SOI) transistor, the FD SOI transistor having a structure including a region within a body on which a gate structure is disposed. The region includes a channel separating the source region and the drain region. Above the source region is disposed a carrier recombination element, which abuts the gate structure and is electrically connected to the region via the channel. The drain region is lightly doped and ballasted to increase breakdown voltage. The FD SOI may be fabricated by forming a body with a thin silicon layer disposed on a buried oxide (BOX). Alternatively, the body may be formed using a partially depleted (PD) SOI where the region formed therein has a reduced thickness in comparison to the overall thickness of the PD SOI. | 04-16-2009 |
| 20090101978 | FIN-TYPE FIELD EFFECT TRANSISTOR STRUCTURE WITH MERGED SOURCE/DRAIN SILICIDE AND METHOD OF FORMING THE STRUCTURE - Disclosed herein are embodiments of a design structure of a multiple fin fin-type field effect transistor (i.e., a multiple fin dual-gate or tri-gate field effect transistor) in which the multiple fins are partially or completely merged by a highly conductive material (e.g., a metal silicide). Merging the fins in this manner allow series resistance to be minimized with little, if any, increase in the parasitic capacitance between the gate and source/drain regions. Merging the semiconductor fins in this manner also allows each of the source/drain regions to be contacted by a single contact via as well as more flexible placement of that contact via. | 04-23-2009 |
| 20090119626 | DESIGN STRUCTURE INCLUDING TRANSISTOR HAVING GATE AND BODY IN DIRECT SELF-ALIGNED CONTACT - A design structure including a transistor having a directly contacting gate and body is disclosed. In one embodiment, the transistor includes a gate; a body; and a dielectric layer extending over the body to insulate the gate from the body along an entire surface of the body except along a portion of at least a sidewall of the body, wherein the gate is in direct contact with the body at the portion. | 05-07-2009 |
| 20090121291 | DENSE CHEVRON NON-PLANAR FIELD EFFECT TRANSISTORS AND METHOD - Disclosed are embodiments of semiconductor structure and a method of forming the semiconductor structure that simultaneously maximizes device density and avoids contacted-gate pitch and fin pitch mismatch, when multiple parallel angled fins are formed within a limited area on a substrate and then traversed by multiple parallel gates (e.g., in the case of stacked, chevron-configured, CMOS devices). This is accomplished by using, not a minimum lithographic fin pitch, but rather by using a fin pitch that is calculated as a function of a pre-selected contacted-gate pitch, a pre-selected fin angle and a pre-selected periodic pattern for positioning the fins relative to the gates within the limited area. Thus, the disclosed structure and method allow for the conversion of a semiconductor product design layout with multiple, stacked, planar FETs in a given area into a semiconductor product design layout with multiple, stacked, chevron-configured, non-planar FETs in the same area. | 05-14-2009 |
| 20090189223 | Complementary Metal Gate Dense Interconnect and Method of Manufacturing - Complementary metal gate dense interconnects and methods of manufacturing the interconnects is provided. The method comprises forming a first metal gate on a wafer and second metal gate on the wafer. A conductive interconnect material is deposited in a space formed between the first metal gate and the second metal gate to provide an electrical connection between the first metal gate and the second metal gate. | 07-30-2009 |
| 20090197382 | MULTI-GATED, HIGH-MOBILITY, DENSITY IMPROVED DEVICES - Disclosed herein are embodiments of an improved method of forming p-type and n-type MUGFETs with high mobility crystalline planes in high-density, chevron-patterned, CMOS devices. Specifically, semiconductor fins are formed in a chevron layout oriented along the centerline of a wafer. Gates are formed adjacent to the semiconductor fins such that they are approximately perpendicular to the centerline. Then, masked implant sequences are performed, during which halo and/or source/drain dopants are implanted into the sidewalls of the semiconductor fins on one side of the chevron layout and then into the sidewalls of the semiconductor fins on the opposite side of the chevron layout. The implant direction used during these implant sequences is substantially orthogonal to the gates in order to avoid mask shadowing, which can obstruct dopant implantation when separation between the semiconductor fins in the chevron layout is scaled (i.e., when device density is increased). | 08-06-2009 |
| 20090206407 | SEMICONDUCTOR DEVICES HAVING TENSILE AND/OR COMPRESSIVE STRESS AND METHODS OF MANUFACTURING - A semiconductor device and method of manufacturing is disclosed which has a tensile and/or compressive strain applied thereto. The method includes forming at least one trench in a material; and filling the at least one trench by an oxidation process thereby forming a strain concentration in a channel of a device. The structure includes a gate structure having a channel and a first oxidized trench on a first of the channel, respectively. The first oxidized trench creates a strain component in the channel to increase device performance. | 08-20-2009 |
| 20090236632 | FET HAVING HIGH-K, VT MODIFYING CHANNEL AND GATE EXTENSION DEVOID OF HIGH-K AND/OR VT MODIFYING MATERIAL, AND DESIGN STRUCTURE - A field effect transistor (FET) including a high dielectric constant (high-k), threshold voltage (Vt) modifying channel and a gate extension devoid of the high-k and/or Vt modifying material, and a related design structure, are disclosed. In one embodiment, a FET may include a gate having a channel region thereunder including a gate insulator portion of a high dielectric constant (high-k) material and a threshold voltage (Vt) modifying portion (e.g., of SiGe); and a gate extension having a region thereunder devoid of at least one of the high-k material or the Vt modifying portion. | 09-24-2009 |
| 20090243000 | METHOD, STRUCTURE AND DESIGN STRUCTURE FOR CUSTOMIZING HISTORY EFFECTS OF SOI CIRCUITS - A design structure is embodied in a machine readable medium for designing, manufacturing, or testing a design. The design structure includes a high-leakage dielectric formed over an active region of a FET and a low-leakage dielectric formed on the active region and adjacent the high-leakage dielectric. The low-leakage dielectric has a lower leakage than the high-leakage dielectric. Also provided is a structure and method of fabricating the structure. | 10-01-2009 |
| 20090260669 | METAL-GATE THERMOCOUPLE - A metal gate thermocouple is provided. The thermocouple is configured to measure local temperatures of a device. The thermocouple is a passive device which senses temperature using the thermoelectric principle that when two dissimilar electrically conductive materials are joined, an electrical potential (voltage) is developed between the two materials. The voltage between the materials varies with the temperature of the junction (joint) between the materials. The thermocouple device includes a first conductor comprising a first material formed over a thin oxide layer or a shallow trench isolation (STI) structure and a second conductor comprising a second material formed over the thin oxide layer or the STI structure. The second conductor overlaps with the first conductor to form a thermocouple junction or dimension at least more than an alignment tolerance. The first and second materials are chosen such that the thermocouple junction formed between them exhibits a non-zero Seebeck coefficient. A conductive film formed over the first conductor and the second conductor and a non-conductive void or film is formed over the thermocouple junction. | 10-22-2009 |
| 20090261380 | TRANSISTORS HAVING ASYMETRIC STRAINED SOURCE/DRAIN PORTIONS - A semiconductor structure. The structure includes (a) a fin region having (i) a first source/drain portion having a first surface and a third surface, wherein the first and third surfaces are (A) parallel to each other and (B) not coplanar, (ii) a second source/drain portion having a second surface and a fourth surface, wherein the second and fourth surfaces are (A) parallel to each other and (B) not coplanar, and (iii) a channel region; (b) a gate dielectric layer; (c) a gate electrode region, wherein the gate dielectric layer (i) is sandwiched between, and (ii) electrically insulates the gate electrode region and the channel region; and (d) first second strain creating regions on the third and fourth surfaces, respectively, wherein the first and second strain creating regions comprise a strain creating material. | 10-22-2009 |
| 20090261415 | FULLY-DEPLETED LOW-BODY DOPING FIELD EFFECT TRANSISTOR (FET) WITH REVERSE SHORT CHANNEL EFFECTS (SCE) INDUCED BY SELF-ALIGNED EDGE BACK-GATE(S) - Disclosed are embodiments of a field effect transistor (FET) and, more particularly, a fully-depleted, thin-body (FDTB) FET that allows for scaling with minimal short channel effects, such as drain induced barrier lowering (DIBL) and saturation threshold voltage (Vtsat) roll-off, at shorter channel lengths. The FDTB FET embodiments are configured with either an edge back-gate or split back-gate that can be biased in order to selectively adjust the potential barrier between the source/drain regions and the channel region for minimizing off-state leakage current between the drain region and the source region and/or for varying threshold voltage. These unique back-gate structures avoid the need for halo doping to ensure linear threshold voltage (Vtlin) roll-up at smaller channel lengths and, thus, avoid across-chip threshold voltage variations due to random doping fluctuations. Also disclosed are method embodiments for forming such FETs. | 10-22-2009 |
| 20090261425 | FINFETs SINGLE-SIDED IMPLANT FORMATION - A method patterns pairs of semiconducting fins on an insulator layer and then patterns a linear gate conductor structure over and perpendicular to the fins. Next, the method patterns a mask on the insulator layer adjacent the fins such that sidewalls of the mask are parallel to the fins and are spaced from the fins a predetermined distance. The method performs an angled impurity implant into regions of the fins not protected by the gate conductor structure and the mask. This process forms impurity concentrations within the fins that are asymmetric and that mirror one another in adjacent pairs of fins. | 10-22-2009 |
| 20090263949 | TRANSISTORS HAVING ASYMMETRIC STRAINED SOURCE/DRAIN PORTIONS - A structure formation method. First, a structure is provided including (a) a fin region comprising (i) a first source/drain portion having a first surface and a third surface parallel to each other, not coplanar, and both exposed to a surrounding ambient, (ii) a second source/drain portion having a second surface and a fourth surface parallel to each other, not coplanar, and both exposed to the surrounding ambient, and (iii) a channel region disposed between the first and second source/drain portions, (b) a gate dielectric layer, and (c) a gate electrode region, wherein the gate dielectric layer (i) is sandwiched between, and (ii) electrically insulates the gate electrode region and the channel region. Next, a patterned covering layer is used to cover the first and second surfaces but not the third and fourth surfaces. Then, the first and second source/drain portions are etched at the third and fourth surfaces, respectively. | 10-22-2009 |
| 20090267156 | DEVICE STRUCTURES INCLUDING DUAL-DEPTH TRENCH ISOLATION REGIONS AND DESIGN STRUCTURES FOR A STATIC RANDOM ACCESS MEMORY - Device structures and design structures for a static random access memory. The device structure includes a well of a first conductivity type in a semiconductor layer, first and second deep trench isolation regions in the semiconductor layer that laterally bound a device region in the well, and first and second pluralities of doped regions of a second conductivity type in the first device region. A shallow trench isolation region extends laterally across in the device region to connect the first and second deep trench isolation regions, and is disposed in the device region between the first and second pluralities of doped regions. The shallow trench isolation region extends from the top surface into the semiconductor layer to a first depth such that the well is continuous beneath the shallow trench isolation region. A gate stack controls carrier flow between a pair of the first plurality of doped regions. | 10-29-2009 |
| 20090269897 | METHODS OF FABRICATING DUAL-DEPTH TRENCH ISOLATION REGIONS FOR A MEMORY CELL - Methods for fabricating dual-depth trench isolation regions for a memory cell. First and second deep trench isolation regions are formed in the semiconductor layer that laterally bound a device region in a well of a first conductivity type in the semiconductor layer. First and second pluralities of doped regions of a second conductivity type are formed in the device region. A shallow trench isolation region is formed that extends laterally across the device region from the first deep trench isolation region to the second deep trench isolation region. The shallow trench isolation region is disposed in the device region between the first and second pluralities of doped regions. The shallow trench isolation region extends into the semiconductor layer to a depth such that the well is continuous beneath the shallow trench isolation region. A gate stack controls carrier flow between a pair of the first plurality of doped regions. | 10-29-2009 |
| 20090295432 | CMOS BACK-GATED KEEPER TECHNIQUE - A novel methodology for the construction and operation of logical circuits and gates that make use of and contact to a fourth terminal (substrates/bodies) of MOSFET devices is described in detail. The novel construction and operation provides for maintaining such body-contacted MOSFET devices at a lower threshold voltage (V | 12-03-2009 |
| 20090298250 | BIPOLAR TRANSISTOR AND BACK-GATED TRANSISTOR STRUCTURE AND METHOD - A structure is disclosed including a substrate including an insulator layer on a bulk layer, and a bipolar transistor in a first region of the substrate, the bipolar transistor including at least a portion of an emitter region in the insulator layer. Another disclosed structure includes an inverted bipolar transistor in a first region of a substrate including an insulator layer on a bulk layer, the inverted bipolar transistor including an emitter region, and a back-gated transistor in a second region of the substrate, wherein a back-gate conductor of the back-gated transistor and at least a portion of the emitter region are in the same layer of material. A method of forming the structures including a bipolar transistor and back-gated transistor together is also disclosed. | 12-03-2009 |
| 20090302386 | SOI TRANSISTOR HAVING A CARRIER RECOMBINATION STRUCTURE IN A BODY - A top semiconductor layer is formed with two different thicknesses such that a step is formed underneath a body region of a semiconductor-on-insulator (SOI) field effect transistor at the interface between a top semiconductor layer and an underlying buried insulator layer. The interface and the accompanying interfacial defects in the body region provide recombination centers, which increase the recombination rate between the holes and electrons in the body region. Optionally, a spacer portion, comprising a material that functions as recombination centers, is formed on sidewalls of the step to provide an enhanced recombination rate between holes and electrons in the body region, which increases the bipolar breakdown voltage of a SOI field effect transistor. | 12-10-2009 |
| 20090302402 | MUGFET WITH STUB SOURCE AND DRAIN REGIONS - The present invention provides a semiconductor device that includes at least one semiconductor Fin structure atop the surface of a substrate; the semiconducting fin structure including a channel of a first conductivity type and source/drain regions of a second conductivity type, the source/drain regions present at each end of the semiconductor fin structure; a gate structure immediately adjacent to the semiconductor fin structure, a dielectric spacer abutting each sidewall of the gate structure wherein the each end of the fin structure extends a dimension that is less than about ΒΌ a length of the Si-containing fin structure from a sidewall of the dielectric spacer; and a semiconductor region to the each end of the semiconductor fin structure, wherein the semiconductor region to the each end of the semiconductor fin structure is separated from the gate structure by the dielectric spacer. | 12-10-2009 |
| 20090309139 | ASYMMETRIC GATE ELECTRODE AND METHOD OF MANUFACTURE - The invention relates to an asymmetric gate electrode and method of manufacturing an asymmetric gate electrode. The method includes: forming a source region and drain region in a substrate; forming a symmetrical gate structure over a channel formed between the source region and the drain region; depositing a material on the substrate and planarizing the material to a top of the symmetrical gate structure; recessing the symmetrical gate structure to below a surface of the material; forming spacers in the recess; protecting one edge of the spacer while etching another edge of the spacer to remove a portion thereof; and recessing the symmetrical gate structure on a side closest to the source region while the another edge of the spacer protects the symmetrical gate structure on a side closest to the drain region to form an asymmetrical gate electrode. | 12-17-2009 |
| 20090319973 | SPACER FILL STRUCTURE, METHOD AND DESIGN STRUCTURE FOR REDUCING DEVICE VARIATION - A design structure is provided for spacer fill structures and, more particularly, spacer fill structures, a method of manufacturing and a design structure for reducing device variation is provided. The structure includes a plurality of dummy fill shapes in different areas of a device which are configured such that gate perimeter to gate area ratio will result in a total perimeter density being uniform across a chip. | 12-24-2009 |
| 20100015765 | SHALLOW AND DEEP TRENCH ISOLATION STRUCTURES IN SEMICONDUCTOR INTEGRATED CIRCUITS - A semiconductor structure fabrication method. The method includes providing a semiconductor structure which includes a first semiconductor layer and a dielectric bottom portion in the first semiconductor layer. A second semiconductor layer on the first semiconductor layer is formed. The first and second semiconductor layers include a semiconductor material. A dielectric top portion and a first STI (Shallow Trench Isolation) region are formed in the second semiconductor layer. The dielectric top portion is in direct physical contact with the dielectric bottom portion. | 01-21-2010 |
| 20100167504 | Methods of Fabricating Nanostructures - A method is shown for fabricating nanostructures, and more particularly, to methods of fabricating silicon nanowires. The method of manufacturing a nanowire includes forming a sandwich structure of SiX material and material Si over a substrate and etching the sandwich structure to expose sidewalls of the Si material and the SiX material. The method further includes etching the SiX material to expose portions of the Si material and etching the exposed portions of the Si material. The method also includes breaking away the Si material to form silicon nanowires. | 07-01-2010 |
| 20100289082 | ISOLATION WITH OFFSET DEEP WELL IMPLANTS - A method implants impurities into well regions of transistors. The method prepares a first mask over a substrate and performs a first shallow well implant through the first mask to implant first-type impurities to a first depth of the substrate. The first mask is removed and a second mask is prepared over the substrate. The method performs a second shallow well implant through the second mask to implant second-type impurities to the first depth of the substrate and then removes the second mask. A third mask is prepared over the substrate. The third mask has openings smaller than openings in the first mask and the second mask. A first deep well implant is performed through the third mask to implant the first-type impurities to a second depth of the substrate, the second depth of the substrate being greater than the first depth of the substrate. The third mask is removed and a fourth mask is prepared over the substrate, the fourth mask has openings smaller than the openings in the first mask and the second mask. Then, a second deep well implant is performed through the fourth mask to implant the second-type impurities to the second depth of the substrate. | 11-18-2010 |
| 20100301419 | INTEGRATED CIRCUIT DEVICE WITH DEEP TRENCH ISOLATION REGIONS FOR ALL INTER-WELL AND INTRA-WELL ISOLATION AND WITH A SHARED CONTACT TO A JUNCTION BETWEEN ADJACENT DEVICE DIFFUSION REGIONS ANDAN UNDERLYING FLOATING WELL SECTION - Disclosed are embodiments of an improved integrated circuit device structure (e.g., a static random access memory array structure or other integrated circuit device structure incorporating both P-type and N-type devices) and a method of forming the structure that uses DTI regions for all inter-well and intra-well isolation and, thereby provides a low-cost isolation scheme that avoids FET width variations due to STI-DTI misalignment. Furthermore, because the DTI regions used for intra-well isolation effectively create some floating well sections, which must each be connected to a supply voltage (e.g., Vdd) to prevent threshold voltage (Vt) variations, the disclosed integrated circuit device also includes a shared contact to a junction between the diffusion regions of adjacent devices and an underlying floating well section. This shared contact eliminates the cost and area penalties that would be incurred if a discrete supply voltage contact was required for each floating well section. | 12-02-2010 |
| 20110057258 | DUAL STRESS DEVICE AND METHOD - A semiconductor device including semiconductor material having a bend and a trench feature formed at the bend, and a gate structure at least partially disposed in the trench feature. A method of fabricating a semiconductor structure including forming a semiconductor material with a trench feature over a layer, forming a gate structure at least partially in the trench feature, and bending the semiconductor material such that stress is induced in the semiconductor material in an inversion channel region of the gate structure. | 03-10-2011 |
| 20110062240 | DEVICE AND METHOD FOR PROVIDING AN INTEGRATED CIRCUIT WITH A UNIQUE INDENTIFICATION - A device and method for providing an integrated circuit with a unique identification. The device is usable on an integrated circuit (IC) for generating an identification (ID) identifying the IC and includes a plurality of identification cells each utilizing one of a four wire resistor, thin film resistors, and an inverter pair. A measurement circuit measures a parameter of each cell and is utilized in generating the ID in response thereto. | 03-17-2011 |
| 20110068399 | INTEGRATED CIRCUIT DEVICE WITH SERIES-CONNECTED FIELD EFFECT TRANSISTORS AND INTEGRATED VOLTAGE EQUALIZATION AND METHOD OF FORMING THE DEVICE - Disclosed is an integrated circuit device having series-connected planar or non-planar field effect transistors (FETs) with integrated voltage equalization and a method of forming the device. The series-connected FETs comprise gates positioned along a semiconductor body to define the channel regions for the series-connected FETs. Source/drain regions are located within the semiconductor body on opposing sides of the channel regions such that each portion of the semiconductor body between adjacent gates comprises one source/drain region for one field effect transistor abutting another source/drain region for another field effect transistor. Integrated voltage equalization is achieved through a conformal conductive layer having a desired resistance and positioned over the series-connected FETs such that it is electrically isolated from the gates, but in contact with the source/drain regions within the semiconductor body. | 03-24-2011 |
| 20110068414 | INTEGRATED CIRCUIT DEVICE WITH SERIES-CONNECTED FIN-TYPE FIELD EFFECT TRANSISTORS AND INTEGRATED VOLTAGE EQUALIZATION AND METHOD OF FORMING THE DEVICE - Disclosed is an integrated circuit device having stacked fin-type field effect transistors (FINFETs) with integrated voltage equalization and a method. A multi-layer fin includes a semiconductor layer, an insulator layer above the semiconductor layer and a high resistance conductor layer above the insulator layer. For each FINFET, a gate is positioned on the sidewalls and top surface of the fin and source/drain regions are within the semiconductor layer on both sides of the gate. Thus, the portion of the semiconductor layer between any two gates contains a source/drain region of one FINFET abutting a source/drain region of another. Conductive straps are positioned on opposing ends of the fin and also between adjacent gates in order to electrically connect the semiconductor layer to the conductor layer. Contacts electrically connect the conductive straps at the opposing ends of the fin to positive and negative supply voltages, respectively. | 03-24-2011 |
| 20110095267 | Nanowire Stress Sensors and Stress Sensor Integrated Circuits, Design Structures for a Stress Sensor Integrated Circuit, and Related Methods - Stress sensors and stress sensor integrated circuits using one or more nanowire field effect transistors as stress-sensitive elements, as well as design structures for a stress sensor integrated circuit embodied in a machine readable medium for designing, manufacturing, or testing an integrated circuit, and related methods thereof. The stress sensors and stress sensor integrated circuits include one or more pairs of gate-all-around field effect transistors, which include one or more nanowires as a channel region. The nanowires of each of the field effect transistors are configured to change in length in response to a mechanical stress transferred from an object. A voltage output difference from the field effect transistors indicates the magnitude of the transferred mechanical stress. | 04-28-2011 |
| 20110101449 | ASYMMETRIC FIELD EFFECT TRANSISTOR STRUCTURE AND METHOD - Disclosed are embodiments of an asymmetric field effect transistor structure and a method of forming the structure in which both series resistance in the source region (R | 05-05-2011 |
| 20110121862 | CIRCUIT WITH STACKED STRUCTURE AND USE THEREOF - An NAND circuit has a stacked structure having at least one symmetric NFET at a bottom of the stack. More particularly, the circuit has a stacked structure which includes an asymmetric FET and a symmetric FET. The symmetric FET is placed at the bottom of the stacked structure closer to ground than the asymmetric FET. | 05-26-2011 |
| 20110133280 | DIFFERENT THICKNESS OXIDE SILICON NANOWIRE FIELD EFFECT TRANSISTORS - A method (that produces a structure) patterns at least two wires of semiconductor material such that a first wire of the wires has a larger perimeter than a second wire of the wires. The method performs an oxidation process simultaneously on the wires to form a first gate oxide on the first wire and a second gate oxide on the second wire. The first gate oxide is thicker than the second gate oxide. The method also forms gate conductors over the first gate oxide and the second gate oxide, forms sidewall spacers on the gate conductors, and dopes portions of the first wire and the second wire not covered by the sidewall spacers and the gate conductors to form source and drain regions within the first wire and the second wire. | 06-09-2011 |
| 20110133310 | INTEGRATED CIRCUIT AND A METHOD USING INTEGRATED PROCESS STEPS TO FORM DEEP TRENCH ISOLATION STRUCTURES AND DEEP TRENCH CAPACITOR STRUCTURES FOR THE INTEGRATED CIRCUIT - Disclosed is an integrated circuit having at least one deep trench isolation structure and a deep trench capacitor. A method of forming the integrated circuit incorporates a single etch process to simultaneously form first trench(s) and a second trenches for the deep trench isolation structure(s) and a deep trench capacitor, respectively. Following formation of a buried capacitor plate adjacent to the lower portion of the second trench, the trenches are lined with a conformal insulator layer and filled with a conductive material. Thus, for the deep trench capacitor, the conformal insulator layer functions as the capacitor dielectric and the conductive material as a capacitor plate in addition to the buried capacitor plate. A shallow trench isolation (STI) structure formed in the substrate extending across the top of the first trench(es) encapsulates the conductive material therein, thereby creating the deep trench isolation structure(s). | 06-09-2011 |
