Patent application number | Description | Published |
20080211064 | DEEP TRENCH BASED FAR SUBCOLLECTOR REACHTHROUGH - A far subcollector, or a buried doped semiconductor layer located at a depth that exceeds the range of conventional ion implantation, is formed by ion implantation of dopants into a region of an initial semiconductor substrate followed by an epitaxial growth of semiconductor material. A reachthrough region to the far subcollector is formed by outdiffusing a dopant from a doped material layer deposited in the at least one deep trench that adjoins the far subcollector. The reachthrough region may be formed surrounding the at least one deep trench or only on one side of the at least one deep trench. If the inside of the at least one trench is electrically connected to the reachthrough region, a metal contact may be formed on the doped fill material within the at least one trench. If not, a metal contact is formed on a secondary reachthrough region that contacts the reachthrough region. | 09-04-2008 |
20080237789 | INTEGRATED CIRCUIT STUCTURE INCORPORATING AN INDUCTOR, AN ASSOCIATED DESIGN METHOD AND AN ASSOCIATED DESIGN SYSTEM - Disclosed are embodiments of a circuit (e.g., an electrostatic discharge (ESD) circuit), a design methodology and a design system. In the circuit, an ESD device is wired to a first metal level (e.g., M | 10-02-2008 |
20080251846 | METHOD AND STRUCTURE FOR LOW CAPACITANCE ESD ROBUST DIODES - A diode having a capacitance below 0.1 pF and a breakdown voltage of at least 500V. The diode has an anode of a first conductivity type and a cathode of a second conductivity type disposed below the anode. At least one of the cathode and anode have multiple, vertically abutting diffusion regions. The cathode and anode are disposed between and bounded by adjacent isolation regions. | 10-16-2008 |
20080254609 | APPARATUS AND METHOD FOR ELECTRONIC FUSE WITH IMPROVED ESD TOLERANCE - Method of making an electronic fuse blow resistor structure. In one embodiment, the method includes forming an insulator film, depositing a conductor on the insulator film, and after the depositing, etching the conductor to form a plurality of spaced apart non-conductive regions and a plurality of spaced-apart conductive regions. In another embodiment, the method includes forming the insulator film, forming a conductive sheet, and sub-dividing the conductive sheet into the plurality of conductive regions. | 10-16-2008 |
20080258173 | VERTICAL P-N JUNCTION DEVICE AND METHOD OF FORMING SAME - A P-N junction device and method of forming the same are disclosed. The P-N junction device may include a P-N diode, a PiN diode or a thyristor. The P-N junction device may have a monocrystalline or polycrystalline raised anode. In one embodiment, the P-N junction device results in a raised polycrystalline silicon germanium (SiGe) anode. In another embodiment, the P-N junction device includes a first terminal (anode) including a conductor layer positioned above an upper surface of a substrate and a remaining structure positioned in the substrate, the first terminal positioned over an opening in an isolation region; and a second terminal (cathode contact) positioned over the opening in the isolation region adjacent the first terminal. This latter embodiment reduces parasitic resistance and capacitance, and decreases the required size of a cathode implant area since the cathode contact is within the same STI opening as the anode. | 10-23-2008 |
20080265333 | STRUCTURE AND METHOD FOR ENHANCED TRIPLE WELL LATCHUP ROBUSTNESS - Disclosed is a triple well CMOS device structure that addresses the issue of latchup by adding an n+ buried layer not only beneath the p-well to isolate the p-well from the p-substrate but also beneath the n-well. The structure eliminates the spacing issues between the n-well and n+ buried layer by extending the n+ buried layer below the entire device. The structure also addresses the issue of threshold voltage scattering by providing a p+ buried layer below the entire device under the n+ buried layer or below the p-well side of the device only either under or above the n+ buried layer) Latchup robustness can further be improved by incorporating into the device an isolation structure that eliminates lateral pnp, npn, or pnpn devices and/or a sub-collector region between the n+ buried layer and the n-well. | 10-30-2008 |
20080290524 | THROUGH VIA IN ULTRA HIGH RESISTIVITY WAFER AND RELATED METHODS - A through via in an ultra high resistivity wafer and related methods are disclosed. A method for forming a through via comprises: providing a semiconductor wafer including a first silicon layer, a buried dielectric layer, and a substrate; forming a device on the first silicon; and forming a via from a side of the substrate opposite to the buried dielectric layer and through the substrate. | 11-27-2008 |
20080297975 | VERTICAL PARALLEL PLATE CAPACITOR STRUCTURES - Vertical parallel plate (VPP) capacitor structures that utilize different spacings between conductive plates in different levels of the capacitor stack. The non-even spacings of the conductive plates in the capacitor stack decrease the susceptibility of the capacitor stack of the VPP capacitor to ESD-promoted failures. The non-even spacings may be material specific in that, for example, the spacings between adjacent conductive plates in different levels of the capacitor stack may be chosen based upon material failure mechanisms for plates containing different materials. | 12-04-2008 |
20080301592 | METHODOLOGY FOR AUTOMATED DESIGN OF VERTICAL PARALLEL PLATE CAPACITORS - Apparatus and program product for designing vertical parallel plate (VPP) capacitor structures in which the capacitor plates in different conductive layers of the capacitor stack have a different physical spacing. The methodology optimizes the physical spacing of the plates in each conductive layer to achieve a targeted electrostatic discharge protection level and, thereby, supply electrostatic discharge robustness. | 12-04-2008 |
20080311723 | TUNABLE SEMICONDUCTOR DIODES - A diode structure fabrication method. In a P− substrate, an N+ layer is implanted. The N+ layer has an opening whose size affects the breakdown voltage of the diode structure. Upon the N+ layer, an N− layer is formed. Then, a P+ region is formed to serve as an anode of the diode structure. An N+ region can be formed on the surface of the substrate to serve as a cathode of the diode structure. By changing the size of the opening in the N+ layer during fabrication, the breakdown voltage of the diode structure can be changed (tuned) to a desired value. | 12-18-2008 |
20090001414 | STRUCTURES AND METHODS OF FORMING SIGE AND SIGEC BURIED LAYER FOR SOI/SIGE TECHNOLOGY - Semiconductor structures and methods of forming semiconductor structures, and more particularly to structures and methods of forming SiGe and/or SiGeC buried layers for SOI/SiGe devices. An integrated structure includes discontinuous, buried layers having alternating Si and SiGe or SiGeC regions. The structure further includes isolation structures at an interface between the Si and SiGe or SiGeC regions to reduce defects between the alternating regions. Devices are associated with the Si and SiGe or SiGeC regions. | 01-01-2009 |
20090001417 | STRUCTURES AND METHODS OF FORMING SIGE AND SIGEC BURIED LAYER FOR SOI/SIGE TECHNOLOGY - Semiconductor structures and methods of forming semiconductor structures, and more particularly to structures and methods of forming SiGe and/or SiGeC buried layers for SOI/SiGe devices. An integrated structure includes discontinuous, buried layers having alternating Si and SiGe or SiGeC regions. The structure further includes isolation structures at an interface between the Si and SiGe or SiGeC regions to reduce defects between the alternating regions. Devices are associated with the Si and SiGe or SiGeC regions. The invention is also directed to a design structure on which a circuit resides. | 01-01-2009 |
20090019414 | HIGH TOLERANCE TCR BALANCED HIGH CURRENT RESISTOR FOR RF CMOS AND RF SIGE BICMOS APPLICATIONS AND CADENCED BASED HIERARCHICAL PARAMETERIZED CELL DESIGN KIT WITH TUNABLE TCR AND ESD RESISTOR BALLASTING FEATURE - A resistor device structure and method of manufacture therefore, wherein the resistor device structure invention includes a plurality of alternating conductive film and insulative film layers, at least two of the conductive film layers being electrically connected in parallel to provide for high current flow through the resistor device at high frequencies with increased temperature and mechanical stability. The alternating conductive film and insulative film layers may be of a planar or non-planar geometric spatial orientation. The alternating conductive film and insulative film layers may include lateral and vertical portions designed to enable a uniform current density flow within the structure itself through a self-ballasting effect within the physical resistor. A computer aided design tool with graphical and schematic features is provided to enable generation of hierarchical parameterized cells for a resistor element with the ability to provide customization, personalization and tunability of TCR, TCR matching, and high current and ESD robustness. | 01-15-2009 |
20090035933 | DENDRITE GROWTH CONTROL CIRCUIT - A circuit is provided which prevents dendrite formation on interconnects during semiconductor device processing due to a dendrite-forming current. The circuit includes a switch located in at least one of the dendrite-forming current paths. The switch is configured to be open or in the “off” state during processing, and is configured to be closed or in the “on” state after processing to allow proper functioning of the semiconductor device. The switch may include an nFET or pFET, depending on the environment in which it is used to control or prevent dendrite formation. The switch may be configured to change to the “closed” state when an input signal is provided during operation of the fabricated semiconductor device. | 02-05-2009 |
20090039385 | SEMICONDUCTOR DEVICES - A device comprises a first sub-collector formed in an upper portion of a substrate and a lower portion of a first epitaxial layer and a second sub-collector formed in an upper portion of the first epitaxial layer and a lower portion of a second epitaxial layer. The device further comprises a reach-through structure connecting the first and second sub-collectors and an N-well formed in a portion of the second epitaxial layer and in contact with the second sub-collector and the reach-through structure. The device further comprises N+ diffusion regions in contact with the N-well, a P+ diffusion region in contact with the N-well, and shallow trench isolation structures between the N+ and P+ diffusion regions. | 02-12-2009 |
20090070718 | METHODOLOGY FOR PLACEMENT BASED ON CIRCUIT FUNCTION AND LATCHUP SENSITIVITY - A structure, apparatus and method for circuits to minimize sensitivity to latch. The method includes, for example, identifying element density of at least one functional circuit block and element attributes of elements associated with the at least one functional circuit block. An element density function parameterized from the element attributes is formed. The placement of the at least one functional circuit block is modified relative to other functional circuit blocks based on the element density function to substantially eliminate latching effects in a circuit. | 03-12-2009 |
20090090983 | DUAL WORK FUNCTION HIGH VOLTAGE DEVICES - A transistor has a substrate having a channel region and source and drain regions within the substrate on opposite sides of the channel region. The structure includes a gate oxide above the channel region of the substrate and a gate conductor above the gate oxide. The polysilicon gate conductor comprises a source side positioned toward the source and a drain side positioned toward the drain. The source side comprises a first concentration of conductive doping and the drain side comprises a second concentration of the conductive doping that is less than the first concentration. | 04-09-2009 |
20090101941 | WRAPPED GATE JUNCTION FIELD EFFECT TRANSISTOR - A wrapped gate junction field effect transistor (JFET) with at least one semiconductor channel having a first conductivity type doping is provided. Both sidewalls of each of the at least one semiconductor channel laterally abuts a side gate region having a second conductivity type doping, which is the opposite of the first conductivity doping. Further, the at least one semiconductor channel vertically abuts a top gate region and at least one bottom gate region, both having the second conductivity type doping. The gate electrode, which comprises side gate region, the top gate region, and at least one bottom gate regions, wraps around each of the at least one semiconductor channel to provide tight control of the current, i.e., a low off-current, through the at least one semiconductor channel. By employing multiple channels, the JFET may provide a high on-current. | 04-23-2009 |
20090102016 | DESIGN STRUCTURE INCORPORATING VERTICAL PARALLEL PLATE CAPACITOR STRUCTURES - Design structure embodied in a machine readable medium for designing, manufacturing, or testing a design. The design structure includes a vertical parallel plate capacitor structure with a first plurality of conductive plates and a second plurality of conductive plates having an overlying relationship with the first plurality of conductive plates. The first plurality of conductive plates are spaced apart by a first distance. The second plurality of conductive plates are spaced apart by a second distance different than the first distance | 04-23-2009 |
20090127628 | PRODUCT AND METHOD FOR INTEGRATION OF DEEP TRENCH MESH AND STRUCTURES UNDER A BOND PAD - A structure includes a substrate. A trench structure is arranged within the substrate. A film is placed under an interlevel dielectric pad and between portions of the trench structure. | 05-21-2009 |
20090140343 | LATERAL DIFFUSION FIELD EFFECT TRANSISTOR WITH A TRENCH FIELD PLATE - A dielectric material layer is formed on a bottom surface and sidewalls of a trench in a semiconductor substrate. The silicon oxide layer forms a drift region dielectric on which a field plate is formed. Shallow trench isolation may be formed prior to formation of the drift region dielectric, or may be formed utilizing the same processing steps as the formation of the drift region dielectric. A gate dielectric layer is formed on exposed semiconductor surfaces and a gate conductor layer is formed on the gate dielectric layer and the drift region dielectric. The field plate may be electrically tied to the gate electrode, may be an independent electrode having an external bias, or may be a floating electrode. The field plate biases the drift region to enhance performance and extend allowable operating voltage of a lateral diffusion field effect transistor during operation. | 06-04-2009 |
20090152592 | STRUCTURE FOR A LATCHUP ROBUST ARRAY I/O USING THROUGH WAFER VIA - A design structure including: an I/O cell and an ESD protection circuit in a region of an integrated circuit chip containing logic circuits; an electrically conductive through via extending from a bottom surface of the substrate toward a top surface of the substrate between the I/O cell and an ESD protection circuit and at least one of the logic circuits. | 06-18-2009 |
20090152593 | STRUCTURE FOR A LATCHUP ROBUST GATE ARRAY USING THROUGH WAFER VIA - A structure, method and a design structure for preventing latchup in a gate array. The design structure including: a NFET gate array and a PFET gate array in a substrate; an electrically conductive through via extending from a bottom surface of the substrate toward a top surface of the substrate the NFET gate array and PFET gate array, the through via electrically contacting the P-well. | 06-18-2009 |
20090152632 | LATCHUP ROBUST ARRAY I/O USING THROUGH WAFER VIA - A structure and a method for preventing latchup. The structure including: an I/O cell and an ESD protection circuit in a region of an integrated circuit chip containing logic circuits; an electrically conductive through via extending from a bottom surface of the substrate toward a top surface of the substrate between the I/O cell and an ESD protection circuit and at least one of the logic circuits. | 06-18-2009 |
20090152680 | ELECTROSTATIC DISCHARGE PROTECTION FOR BIPOLAR SEMICONDUCTOR CIRCUITRY - Multiple emitter-base regions arc formed on a single contiguous collector. The multiple emitter-base regions are cascoded such that the base of one emitter-base region is directly wired to the emitter of an adjacent emitter-base region. An electrostatic discharge (ESD) protection unit, comprising a single collector and multiple emitter-base regions, provides protection against an ESD event of one type, i.e., a positive or negative voltage surge. The inventive ESD protection structure comprises a parallel connection of two ESD protection units, each providing a discharge path for electrical charges of opposite types, and provides ESD protection for both types of voltage swing in the circuit. | 06-18-2009 |
20090154037 | DESIGN STRUCTURES FOR ELECTROSTATIC DISCHARGE PROTECTION FOR BIPOLAR SEMICONDUCTOR CIRCUITRY - A design structure for electrostatic discharge protection comprises a first data representing a first electrostatic discharge (ESD) protection circuit and a second data representing a second ESD protection circuit. A parallel connection of two ESD protection units, each providing a discharge path for electrical charges of opposite types, provides ESD protection circuit for positive and negative voltage swings in the circuit. Each of the multiple emitter-base regions are cascoded such that the base of one emitter-base region is directly wired to the emitter of an adjacent emitter-base region. The first data represents a first ESD protection unit providing protection on one type of voltage swing, and the second data represents a second ESD protection unit providing protection on the other type of voltage swing. | 06-18-2009 |
20090166798 | DESIGN METHODOLOGY FOR GUARD RING DESIGN RESISTANCE OPTIMIZATION FOR LATCHUP PREVENTION - A design structure is disclosed for a circuit optimizing guard ring design by optimizing the path resistance value between the components of the parasitic lateral bipolar transistors in a CMOS circuit and the power supply or ground. By comparing the calculated path resistance value to a maximum resistance number derived from specifications, elements that need further redesign are identified. Repeated redesign with several redesign options eventually lead to an optimized guard ring structure that provides area-efficient and sufficient latchup protection for the CMOS circuit. A design structure employing such an optimized guard ring is also provided. | 07-02-2009 |
20090179276 | Resistor Ballasted Transistors - A semiconductor chip comprises low voltage complementary metal oxide semiconductor (CMOS) sectors and high voltage lateral double diffused metal oxide semiconductor (LDMOS) sectors and at least one transistor within at least one of the low voltage CMOS sectors. The transistor has a semiconducting channel region within a substrate. A gate conductor is above the top layer of substrate, and the gate conductor is positioned above the channel region. A source/drain region is included in the substrate on a first side of the gate conductor and a lateral source/drain region is included in the substrate on a second side of the gate conductor opposite the first side. The lateral source/drain region is positioned a greater distance from the gate conductor than the source/drain region is positioned from the gate conductor. The embodiments herein also include a source/drain ballast resistor in the substrate between the lateral source/drain region and the gate conductor. | 07-16-2009 |
20090193378 | MODIFYING LAYOUT OF IC BASED ON FUNCTION OF INTERCONNECT AND RELATED CIRCUIT AND DESIGN STRUCTURE - Modifying a layout of an integrated circuit (IC) based on a function of an interconnect therein and a related circuit and design structure are disclosed. In one embodiment, a method includes identifying a function of an interconnect in the layout from data of the layout embodied in a computer readable medium; and modifying the layout to form another layout that accommodates the function of the interconnect. A design structure embodied in a machine readable medium used in a design process, according to one embodiment, may include a circuit including a high voltage interconnect positioned in a dielectric layer, the high voltage interconnect positioned such that no fill is above or below the high voltage interconnect. | 07-30-2009 |
20090210833 | Semiconductor Structure and Method of Designing Semiconductor Structure to Avoid High Voltage Initiated Latch-up in Low Voltage Sectors - Method and semiconductor structure to avoid latch-up. Method includes identifying at least one high voltage device on a semiconductor chip, identifying a circuit on the semiconductor chip separated from the identified at least one high voltage device by a guard ring, evaluating the circuit for a latch-up condition, and when the latch-up condition occurs, adjusting the contact-circuit spacing in the circuit. | 08-20-2009 |
20090261426 | LATERAL DIFFUSION FIELD EFFECT TRANSISTOR WITH DRAIN REGION SELF-ALIGNED TO GATE ELECTRODE - A disposable structure displaced from an edge of a gate electrode and a drain region aligned to the disposable structure is formed. Thus, the drain region is self-aligned to the edge of the gate electrode. The disposable structure may be a disposable spacer, or alternately, the disposable structure may be formed simultaneously with, and comprise the same material as, a gate electrode. After formation of the drain regions, the disposable structure is removed. The self-alignment of the drain region to the edge of the gate electrode provides a substantially constant drift distance that is independent of any overlay variation of lithographic processes. | 10-22-2009 |
20090283854 | Design Structure and Method for Buried Inductors for Ultra-High Resistivity Wafers for SOI/RF SIGE Applications - A design structure is embodied in a machine readable medium for designing, manufacturing, or testing a design. The design structure includes a high resistivity substrate and a buried inductor formed directly in the high resistivity substrate and devoid of an insulating layer therebetween. | 11-19-2009 |
20100025761 | DESIGN STRUCTURE, STRUCTURE AND METHOD OF LATCH-UP IMMUNITY FOR HIGH AND LOW VOLTAGE INTEGRATED CIRCUITS - Design structures, structures and methods of manufacturing structures for providing latch-up immunity for mixed voltage integrated circuits. The structure includes a diffused N-Tub structure embedded in a P-wafer and provided below a retrograde N-well to a non-isolated CMOS logic. | 02-04-2010 |
20100032767 | STRUCTURE AND METHOD OF LATCHUP ROBUSTNESS WITH PLACEMENT OF THROUGH WAFER VIA WITHIN CMOS CIRCUITRY - A method of manufacturing a semiconductor structure includes: forming a trench in a back side of a substrate; depositing a dopant on surfaces of the trench; forming a shallow trench isolation (STI) structure in a top side of the substrate opposite the trench; forming a deep well in the substrate; out-diffusing the dopant into the deep well and the substrate; forming an N-well and a P-well in the substrate; and filling the trench with a conductive material. | 02-11-2010 |
20100117189 | DEEP TRENCH BASED FAR SUBCOLLECTOR REACHTHROUGH - A far subcollector, or a buried doped semiconductor layer located at a depth that exceeds the range of conventional ion implantation, is formed by ion implantation of dopants into a region of an initial semiconductor substrate followed by an epitaxial growth of semiconductor material. A reachthrough region to the far subcollector is formed by outdiffusing a dopant from a doped material layer deposited in the at least one deep trench that adjoins the far subcollector. The reachthrough region may be formed surrounding the at least one deep trench or only on one side of the at least one deep trench. If the inside of the at least one trench is electrically connected to the reachthrough region, a metal contact may be formed on the doped fill material within the at least one trench. If not, a metal contact is formed on a secondary reachthrough region that contacts the reachthrough region. | 05-13-2010 |
20100161304 | METHOD OF INTERCONNECT CHECKING AND VERIFICATION FOR MULTIPLE ELECTROSTATIC DISCHARGE SPECIFICATIONS - A method for designing a semiconductor device circuit comprising a electrostatic discharge (ESD) protection circuit can include device simulations using at least one, for example two or more ESD models, and designing device features such that they are resilient to damage from the two or more ESD testing models. | 06-24-2010 |
20100171148 | SEMICONDUCTOR DEVICES - A device comprises a first sub-collector formed in an upper portion of a substrate and a lower portion of a first epitaxial layer and a second sub-collector formed in an upper portion of the first epitaxial layer and a lower portion of a second epitaxial layer. The device further comprises a reach-through structure connecting the first and second sub-collectors and an N− well formed in a portion of the second epitaxial layer and in contact with the second sub-collector and the reach-through structure. The device further comprises N+ diffusion regions in contact with the N− well, a P+ diffusion region in contact with the N− well, and shallow trench isolation structures between the N+ and P+ diffusion regions. | 07-08-2010 |
20100175035 | INTEGRATED CIRCUIT STRUCTURE INCORPORATING AN INDUCTOR, AN ASSOCIATED DESIGN METHOD AND AN ASSOCIATED DESIGN SYSTEM - Disclosed are embodiments of a circuit (e.g., an electrostatic discharge (ESD) circuit), a design methodology and a design system. In the circuit, an ESD device is wired to a first metal level (e.g., M1). An inductor is formed in a second metal level (e.g., M5) above the first metal level and is aligned over and electrically connected in parallel to the ESD device by a single vertical via stack. The inductor is configured to nullify, for a given application frequency, the capacitance value of the ESD device. The quality factor of the inductor is optimized by providing, on a third metal level (e.g., M3) between the second metal level and the first metal level, a shield to minimize inductive coupling. An opening in the shield allows the via stack to pass through, trading off Q factor reduction for size-scaling and ESD robustness improvements. | 07-08-2010 |
20100244112 | INTEGRATED CIRCUIT STRUCTURES WITH SILICON GERMANIUM FILM INCORPORATED AS LOCAL INTERCONNECT AND/OR CONTACT - Disclosed are integrated circuit structures each having a silicon germanium film incorporated as a local interconnect and/or an electrical contact. These integrated circuit structures provide improved local interconnects between devices and/or increased capacitance to devices without significantly increasing structure surface area or power requirements. Specifically, disclosed are integrated circuit structures that incorporate a silicon germanium film as one or more of the following features: as a local interconnect between devices; as an electrical contact to a device (e.g., a deep trench capacitor, a source/drain region of a transistor, etc.); as both an electrical contact to a deep trench capacitor and a local interconnect between the deep trench capacitor and another device; and as both an electrical contact to a deep trench capacitor and as a local interconnect between the deep trench capacitor and other devices. | 09-30-2010 |
20100244179 | STRUCTURE AND METHOD FOR LATCHUP IMPROVEMENT USING THROUGH WAFER VIA LATCHUP GUARD RING - A method and structure for preventing latchup. The structure includes a latchup sensitive structure and a through wafer via structure bounding the latch-up sensitive structure to prevent parasitic carriers from being injected into the latch-up sensitive structure. | 09-30-2010 |
20100244187 | ESD NETWORK CIRCUIT WITH A THROUGH WAFER VIA STRUCTURE AND A METHOD OF MANUFACTURE - The present invention generally relates to a circuit structure and a method of manufacturing a circuit, and more specifically to an electrostatic discharge (ESD) circuit with a through wafer via structure and a method of manufacture. An ESD structure includes an ESD active device and at least one through wafer via structure providing a low series resistance path for the ESD active device to a substrate. An apparatus includes an input, at least one power rail and an ESD circuit electrically connected between the input and the at least one power rail, wherein the ESD circuit comprises at least one through wafer via structure providing a low series resistance path to a substrate. A method, includes forming an ESD active device on a substrate, forming a ground plane on a backside of the substrate and forming at least one through wafer via electrically connected to a negative power supply of the ESD active device and the ground plane to provide a low series resistance path to the substrate. | 09-30-2010 |
20100321842 | Electrostatic Discharge Structures and Methods of Manufacture - Electrostatic discharge (ESD) structures having a connection to a through wafer via structure and methods of manufacture are provided. The structure includes an electrostatic discharge (ESD) network electrically connected in series to a through wafer via. More specifically, the ESD circuit includes a bond pad and an ESD network located under the bond pad. The ESD circuit further includes a through wafer via structure electrically connected in series directly to the ESD network, and which is also electrically connected to VSS. | 12-23-2010 |
20100327398 | DESIGN STRUCTURE AND METHOD FOR BURIED INDUCTORS FOR ULTRA-HIGH RESISTIVITY WAFERS FOR SOI/RF SIGE APPLICATIONS - A design structure is embodied in a machine readable medium for designing, manufacturing, or testing a design. The design structure includes a high resistivity substrate and a buried inductor formed directly in the high resistivity substrate and devoid of an insulating layer therebetween. | 12-30-2010 |
20110198703 | STRUCTURE AND METHOD OF LATCHUP ROBUSTNESS WITH PLACEMENT OF THROUGH WAFER VIA WITHIN CMOS CIRCUITRY - A method of manufacturing a semiconductor structure includes: forming a trench in a back side of a substrate; depositing a dopant on surfaces of the trench; forming a shallow trench isolation (STI) structure in a top side of the substrate opposite the trench; forming a deep well in the substrate; out-diffusing the dopant into the deep well and the substrate; forming an N-well and a P-well in the substrate; and filling the trench with a conductive material. | 08-18-2011 |
20110227130 | STRUCTURES AND METHODS OF FORMING SIGE AND SIGEC BURIED LAYER FOR SOI/SIGE TECHNOLOGY - Semiconductor structures and methods of forming semiconductor structures, and more particularly to structures and methods of forming SiGe and/or SiGeC buried layers for SOI/SiGe devices. An integrated structure includes discontinuous, buried layers having alternating Si and SiGe or SiGeC regions. The structure further includes isolation structures at an interface between the Si and SiGe or SiGeC regions to reduce defects between the alternating regions. Devices are associated with the Si and SiGe or SiGeC regions. | 09-22-2011 |
20110227166 | STRUCTURE AND METHOD FOR LATCHUP IMPROVEMENT USING THROUGH WAFER VIA LATCHUP GUARD RING - A structure for preventing latchup. The structure includes a latchup sensitive structure and a through wafer via structure bounding the latch-up sensitive structure to prevent parasitic carriers from being injected into the latch-up sensitive structure. | 09-22-2011 |
20120124533 | SEMICONDUCTOR STRUCTURE AND METHOD OF DESIGNING SEMICONDUCTOR STRUCTURE TO AVOID HIGH VOLTAGE INITIATED LATCH-UP IN LOW VOLTAGE SECTORS - A method and semiconductor structure to avoid latch-up is disclosed. The method includes identifying at least one high voltage device on a semiconductor chip, identifying a circuit on the semiconductor chip separated from the identified at least one high voltage device by a guard ring, evaluating the circuit for a latch-up condition, and when the latch-up condition occurs, adjusting the contact-circuit spacing in the circuit. | 05-17-2012 |
20120126319 | LATERAL DIFFUSION FIELD EFFECT TRANSISTOR WITH DRAIN REGION SELF-ALIGNED TO GATE ELECTRODE - A disposable structure displaced from an edge of a gate electrode and a drain region aligned to the disposable structure is formed. Thus, the drain region is self-aligned to the edge of the gate electrode. The disposable structure may be a disposable spacer, or alternately, the disposable structure may be formed simultaneously with, and comprise the same material as, a gate electrode. After formation of the drain regions, the disposable structure is removed. The self-alignment of the drain region to the edge of the gate electrode provides a substantially constant drift distance that is independent of any overlay variation of lithographic processes. | 05-24-2012 |
20120132974 | INTEGRATED CIRCUIT STRUCTURES WITH SILICON GERMANIUM FILM INCORPORATED AS LOCAL INTERCONNECT AND/OR CONTACT - Disclosed are integrated circuit structures each having a silicon germanium film incorporated as a local interconnect and/or an electrical contact. These integrated circuit structures provide improved local interconnects between devices and/or increased capacitance to devices without significantly increasing structure surface area or power requirements. Specifically, disclosed are integrated circuit structures that incorporate a silicon germanium film as one or more of the following features: as a local interconnect between devices; as an electrical contact to a device (e.g., a deep trench capacitor, a source/drain region of a transistor, etc.); as both an electrical contact to a deep trench capacitor and a local interconnect between the deep trench capacitor and another device; and as both an electrical contact to a deep trench capacitor and as a local interconnect between the deep trench capacitor and other devices. | 05-31-2012 |
20120205741 | STRUCTURE AND METHOD FOR BURIED INDUCTORS FOR ULTRA-HIGH RESISTIVITY WAFERS FOR SOI/RF SIGE APPLICATIONS - A design structure is embodied in a machine readable medium for designing, manufacturing, or testing a design. The design structure includes a high resistivity substrate and a buried inductor formed directly in the high resistivity substrate and devoid of an insulating layer therebetween. | 08-16-2012 |
20120238069 | ESD NETWORK CIRCUIT WITH A THROUGH WAFER VIA STRUCTURE AND A METHOD OF MANUFACTURE - A method includes forming an ESD active device on a substrate, forming a ground plane on a backside of the substrate and forming at least one through wafer via electrically connected to a negative power supply of the ESD active device and the ground plane to provide a low series resistance path to the substrate. | 09-20-2012 |
20130154024 | STRUCTURE AND METHOD OF LATCHUP ROBUSTNESS WITH PLACEMENT OF THROUGH WAFER VIA WITHIN CMOS CIRCUITRY - A method of manufacturing a semiconductor structure includes: forming a trench in a back side of a substrate; depositing a dopant on surfaces of the trench; forming a shallow trench isolation (STI) structure in a top side of the substrate opposite the trench; forming a deep well in the substrate; out-diffusing the dopant into the deep well and the substrate; forming an N-well and a P-well in the substrate; and filling the trench with a conductive material. | 06-20-2013 |
20130168818 | DESIGN STRUCTURE, STRUCTURE AND METHOD OF LATCH-UP IMMUNITY FOR HIGH AND LOW VOLTAGE INTEGRATED CIRCUITS - Design structures, structures and methods of manufacturing structures for providing latch-up immunity for mixed voltage integrated circuits. The structure includes a diffused N-Tub structure embedded in a P-wafer and provided below a retrograde N-well to a non-isolated CMOS logic. | 07-04-2013 |
20130299915 | DESIGN STRUCTURE, STRUCTURE AND METHOD OF LATCH-UP IMMUNITY FOR HIGH AND LOW VOLTAGE INTEGRATED CIRCUITS - Design structures, structures and methods of manufacturing structures for providing latch-up immunity for mixed voltage integrated circuits. The structure includes a diffused N-Tub structure embedded in a P-wafer and provided below a retrograde N-well to a non-isolated CMOS logic. | 11-14-2013 |
20140367792 | STRUCTURE AND METHOD OF LATCHUP ROBUSTNESS WITH PLACEMENT OF THROUGH WAFER VIA WITHIN CMOS CIRCUITRY - A method of manufacturing a semiconductor structure includes: forming a trench in a back side of a substrate; depositing a dopant on surfaces of the trench; forming a shallow trench isolation (STI) structure in a top side of the substrate opposite the trench; forming a deep well in the substrate; out-diffusing the dopant into the deep well and the substrate; forming an N-well and a P-well in the substrate; and filling the trench with a conductive material. | 12-18-2014 |