Patent application number | Description | Published |
20080237721 | STRUCTURE AND CIRCUIT TECHNIQUE FOR UNIFORM TRIGGERING OF MULTIFINGER SEMICONDUCTOR DEVICES WITH TUNABLE TRIGGER VOLTAGE - An external current injection source is provided to individual fingers of a multi-finger semiconductor device to provide the same trigger voltage across the multiple fingers. For example, the external injection current is supplied to the body of a MOSFET or the gate of a thyristor. The magnitude of the supplied current from each external current injection source is adjusted so that each finger has the same trigger voltage. The external current supply circuit may comprise diodes or an RC triggered MOSFET. The components of the external current supply circuit may be tuned to achieve a desired predetermined trigger voltage across all fingers of the multi-finger semiconductor device. | 10-02-2008 |
20090108289 | DESIGN STRUCTURE FOR UNIFORM TRIGGERING OF MULTIFINGER SEMICONDUCTOR DEVICES WITH TUNABLE TRIGGER VOLTAGE - A design structure for a circuit providing the same trigger voltage across the multiple fingers is provided, which comprises a data representing an external current injection source connected to individual fingers of a multi-finger semiconductor device. For example, the external injection current is supplied to the body of a MOSFET or the gate of a thyristor. The magnitude of the supplied current from each external current injection source is adjusted so that each finger has the same trigger voltage. The external current supply circuit may comprise diodes or an RC triggered MOSFET. The components of the external current supply circuit may be tuned to achieve a desired predetermined trigger voltage across all fingers of the multi-finger semiconductor device. | 04-30-2009 |
20090160013 | SEMICONDUCTOR DEVICE HEAT DISSIPATION STRUCTURE - A heat generating component of a semiconductor device is located between two heavily doped semiconductor regions in a semiconductor substrate. The heat generating component may be a middle portion of a diode having a light doping, a lightly doped p-n junction between a cathode and anode of a silicon controlled rectifier, or a resistive portion of a doped semiconductor resistor. At least one thermally conductive via comprising a metal or a non-metallic conductive material is place directly on the heat generating component. Alternatively, a thin dielectric layer may be formed between the heat generating component and the at least one thermally conductive via. The at least one thermally conductive via may, or may not, be connected to a back-end-of-line metal wire, which may be connected to higher level of metal wiring or to a handle substrate through a buried insulator layer. | 06-25-2009 |
20090256202 | SEMICONDUCTOR-ON-INSULATOR DEVICE STRUCTURES WITH A BODY-TO-SUBSTRATE CONNECTION FOR ENHANCED ELECTROSTATIC DISCHARGE PROTECTION, AND DESIGN STRUCTURES FOR SUCH SEMICONDUCTOR-ON-INSULATOR DEVICE STRUCTURES - Semiconductor-on-insulator device structures with enhanced electrostatic discharge protection, and design structures for an integrated circuit with device structures exhibiting enhanced electrostatic discharge protection. A device is formed in a body region of a device layer of a semiconductor-on-insulator substrate, which is bounded by an inner peripheral sidewall of an annular dielectric-filled isolation structure that extends from a top surface of the device layer to the insulating layer of the semiconductor-on-insulator substrate. An annular conductive interconnect extends through the body region and the insulating layer to connect the body region with the bulk wafer of the semiconductor-on-insulator substrate. The annular conductive interconnect is disposed inside the inner peripheral sidewall of the isolation structure, which annularly encircles the body region. | 10-15-2009 |
20090302416 | Programmable Electrical Fuse - The present invention relates to e-fuse devices, and more particularly to a device and method of forming an e-fuse device, the method comprising providing a first conductive layer connected to a second conductive layer, the first and second conductive layers separated by a barrier layer having a first diffusivity different than a second diffusivity of the first conductive layer. A void is created in the first conductive layer by driving an electrical current through the e-fuse device. | 12-10-2009 |
20110001551 | CIRCUIT STRUCTURE AND METHOD FOR PROGRAMMING AND RE-PROGRAMMING A LOW POWER, MULTIPLE STATES, ELECTRONIC FUSE (E-FUSE) - Disclosed are embodiments of an e-fuse programming/re-programming circuit. In one embodiment, the e-fuse has two short high atomic diffusion resistance conductor layers positioned on opposite sides and at a same end of a long low atomic diffusion resistance conductor layer. A voltage source is used to vary the polarity and, optionally, the magnitude of voltage applied to the terminals in order to control bi-directional flow of electrons within the long conductor layer and, thereby formation of opens and/or shorts at the long conductor layer-short conductor layer interfaces. The formation of such opens and/or shorts can be used to achieve different programming states. Other circuit structure embodiments incorporate e-fuses with additional conductor layers and additional terminals so as to allow for even more programming states. Also disclosed are embodiments of associated e-fuse programming and re-programming methods. | 01-06-2011 |
20110049683 | STRUCTURES, METHODS AND APPLICATIONS FOR ELECTRICAL PULSE ANNEAL PROCESSES - Structures and methods are provided for nanosecond electrical pulse anneal processes. The method of forming an electrostatic discharge (ESD) N+/P+ structure includes forming an N+ diffusion on a substrate and a P+ diffusion on the substrate. The P+ diffusion is in electrical contact with the N+ diffusion. The method further includes forming a device between the N+ diffusion and the P+ diffusion. A method of annealing a structure or material includes applying an electrical pulse across an electrostatic discharge (ESD) N+/P+ structure for a plurality of nanoseconds. | 03-03-2011 |
20110068364 | BIDIRECTIONAL ELECTROSTATIC DISCHARGE PROTECTION STRUCTURE FOR HIGH VOLTAGE APPLICATIONS - Semiconductor structures providing protection against electrostatic events of both polarities are provided. A pair of p-n junctions is provided underneath a shallow trench isolation portion between a first-conductivity-type well and each of a signal-side second-conductivity-type well and an electrical-ground-side second-conductivity-type well in a semiconductor substrate. A second-conductivity-type doped region and a first-conductivity-type doped region are formed above each second-conductivity-type well such that a portion of the second-conductivity-type well resistively separates the second-conductivity-type doped region and the first-conductivity-type doped region within the semiconductor substrate. Each of the second-conductivity-type doped regions is wired either to a signal node or electrical ground. One of the two npn transistors and one of the two p-n diodes, each inherently present in the semiconductor structure, turn on to provide protection against electrical discharge events involving either type of excessive electrical charges. | 03-24-2011 |
20120043583 | LOW LEAKAGE, LOW CAPACITANCE ELECTROSTATIC DISCHARGE (ESD) SILICON CONTROLLED RECITIFER (SCR), METHODS OF MANUFACTURE AND DESIGN STRUCTURE - A low leakage, low capacitance diode based triggered electrostatic discharge (ESD) silicon controlled rectifiers (SCR), methods of manufacture and design structure are provided. The method includes providing a silicon film on an insulator layer. The method further includes forming isolation regions which extend from an upper side of the silicon layer to the insulator layer. The method further includes forming one or more diodes in the silicon layer, including a p+ region and an n+ region formed in a well bordered by the isolation regions. The isolation regions isolate the one or more diodes in a vertical direction and the insulator layer isolates the one or more diodes from an underlying P or N type substrate, in a horizontal direction. | 02-23-2012 |
20120080717 | BI-DIRECTIONAL BACK-TO-BACK STACKED SCR FOR HIGH-VOLTAGE PIN ESD PROTECTION, METHODS OF MANUFACTURE AND DESIGN STRUCTURES - Bi-directional back-to-back stacked SCRs for high-voltage pin ESD protection, methods of manufacture and design structures are provided. The device includes a symmetrical bi-directional back-to-back stacked silicon controlled rectifier (SCR). An anode of a first of the back-to-back stacked SCR is connected to an input. An anode of a second of the back-to-back stacked SCR is connected to ground. Cathodes of the first and second of the back-to-back stacked SCR are connected together. Each of the symmetrical bi-directional back-to-back SCRs include a pair of diodes directing current towards the cathodes which, upon application of a voltage, become reverse biased effectively and deactivating elements from one of the symmetrical bi-directional back-to-back SCRs while the diodes of another of the symmetrical bi-directional back-to-back SCRs direct current in the same direction as the reverse biased diodes. | 04-05-2012 |
20120120531 | LOW LEAKAGE ELECTROSTATIC DISCHARGE PROTECTION CIRCUIT - A circuit and method for electrostatic discharge (ESD) protection. The ESD protection circuit includes: a silicon control rectifier (SCR) connected between a first voltage rail and a second voltage rail; one or more diodes connected in series in a forward conduction direction between the first voltage rail and a source of a p-channel field effect transistor (PFET); a drain of the PFET connected to the SCR and connected to ground through a current trigger device; and a control circuit connected to the gate of the PFET. | 05-17-2012 |
20120153434 | METAL-INSULATOR-METAL CAPACITORS WITH HIGH CAPACITANCE DENSITY - Metal-insulator-metal (MIM) capacitors and methods for fabricating MIM capacitors. The MIM capacitor includes an interlayer dielectric (ILD) layer with apertures each bounded by a plurality of sidewalls and each extending from the top surface of the ILD layer into the first interlayer dielectric layer. A layer stack, which is disposed on the sidewalls of the apertures and the top surface of the ILD layer, includes a bottom conductive electrode, a top conductive electrode, and a capacitor dielectric between the bottom and top conductive electrodes. | 06-21-2012 |
20120168766 | LATERAL EXTENDED DRAIN METAL OXIDE SEMICONDUCTOR FIELD EFFECT TRANSISTOR (LEDMOSFET) WITH TAPERED DIELECTRIC PLATES TO ACHIEVE A HIGH DRAIN-TO-BODY BREAKDOWN VOLTAGE, A METHOD OF FORMING THE TRANSISTOR AND A PROGRAM STORAGE DEVICE FOR DESIGNING THE TRANSISTOR - A lateral, extended drain, metal oxide semiconductor, field effect transistor (LEDMOSFET) with a high drain-to-body breakdown voltage (Vb) incorporates gate structure extensions on opposing sides of a drain drift region. The extensions are tapered such that a distance between each extension and the drift region increases linearly from one end adjacent to the channel region to another end adjacent to the drain region. In one embodiment, these extensions can extend vertically through the isolation region that surrounds the LEDMOSFET. In another embodiment, the extensions can sit atop the isolation region. In either case, the extensions create a strong essentially uniform horizontal electric field profile within the drain drift. Also disclosed are a method for forming the LEDMOSFET with a specific Vb by defining the dimensions of the extensions and a program storage device for designing the LEDMOSFET to have a specific Vb. | 07-05-2012 |
20120168817 | LATERAL EXTENDED DRAIN METAL OXIDE SEMICONDUCTOR FIELD EFFECT TRANSISTOR (LEDMOSFET) HAVING A HIGH DRAIN-TO-BODY BREAKDOWN VOLTAGE (Vb), A METHOD OF FORMING AN LEDMOSFET, AND A SILICON-CONTROLLED RECTIFIER (SCR) INCORPORATING A COMPLEMENTARY PAIR OF LEDMOSFETS - Disclosed are embodiments of a lateral, extended drain, metal oxide semiconductor, field effect transistor (LEDMOSFET) having a high drain-to-body breakdown voltage. Discrete conductive field (CF) plates are adjacent to opposing sides of the drain drift region, each having an angled sidewall such that the area between the drain drift region and the CF plate has a continuously increasing width along the length of the drain drift region from the channel region to the drain region. The CF plates can comprise polysilicon or metal structures or dopant implant regions within the same semiconductor body as the drain drift region. The areas between the CF plates and the drain drift region can comprise tapered dielectric regions or, alternatively, tapered depletion regions within the same semiconductor body as the drain drift region. Also disclosed are embodiments of a method for forming an LEDMOSFET and embodiments of a silicon-controlled rectifier (SCR) incorporating such LEDMOSFETs. | 07-05-2012 |
20120168878 | FIELD EFFECT TRANSISTOR HAVING OHMIC BODY CONTACT(S), AN INTEGRATED CIRCUIT STRUCTURE INCORPORATING STACKED FIELD EFFECT TRANSISTORS WITH SUCH OHMIC BODY CONTACTS AND ASSOCIATED METHODS - Disclosed is a field effect transistor (FET), in which ohmic body contact(s) are placed relatively close to the active region. The FET includes a semiconductor layer, where the active region and body contact region(s) are defined by a trench isolation structure and where a body region is below and abuts the active region, the trench isolation structure and the body contact region(s). A gate traverses the active region. Dummy gate(s) are on the body contact region(s). A contact extends through each dummy gate to the body contact region below. Dielectric material isolates the contact(s) from the dummy gate(s). During processing, the dummy gate(s) act as blocks to ensure that the body contact regions are not implanted with source/drain dopants or source/drain extension dopants and, thereby to ensure that the body contacts, as formed, are ohmic. Also disclosed are an integrated circuit structure with stacked FETs, having such ohmic body contacts, and associated methods. | 07-05-2012 |
20120178222 | SILICON CONTROLLED RECTIFIERS (SCR), METHODS OF MANUFACTURE AND DESIGN STRUCTURES - Silicon controlled rectifiers (SCR), methods of manufacture and design structures are disclosed herein. The method includes forming a common P-well on a buried insulator layer of a silicon on insulator (SOI) wafer. The method further includes forming a plurality of silicon controlled rectifiers (SCR) in the P-well such that N+ diffusion cathodes of each of the plurality of SCRs are coupled together by the common P-well. | 07-12-2012 |
20120181608 | SEMICONDUCTOR STRUCTURES WITH THINNED JUNCTIONS AND METHODS OF MANUFACTURE - A method of forming a semiconductor structure, including forming a channel in a first portion of a semiconductor layer and forming a doped extension region in a second portion of the semiconductor layer abutting the channel on a first side and abutting an insulator material on a bottom side. The first portion of the semiconductor layer is thicker than the second portion of the semiconductor layer. | 07-19-2012 |
20120187525 | SEMICONDUCTOR-ON-INSULATOR DEVICE WITH ASYMMETRIC STRUCTURE - Device structures with a reduced junction area in an SOI process, methods of making the device structures, and design structures for a lateral diode. The device structure includes one or more dielectric regions, such as STI regions, positioned in the device region and intersecting the p-n junction between an anode and cathode. The dielectric regions, which may be formed using shallow trench isolation techniques, function to reduce the width of a p-n junction with respect to the width area of the cathode at a location spaced laterally from the p-n junction and the anode. The width difference and presence of the dielectric regions creates an asymmetrical diode structure. The volume of the device region occupied by the dielectric regions is minimized to preserve the volume of the cathode and anode. | 07-26-2012 |
20120190133 | THROUGH SILICON VIA REPAIR - Methods and systems for altering the electrical resistance of a wiring path. The electrical resistance of the wiring path is compared with a target electrical resistance value. If the electrical resistance of the wiring path exceeds the target electrical resistance value, an electrical current is selectively applied to the wiring path to physically alter a portion of the wiring path. The current may be selected to alter the wiring path such that the electrical resistance drops to a value less than or equal to the target electrical resistance value. | 07-26-2012 |
20120257317 | RC-triggered Semiconductor Controlled Rectifier for ESD Protection of Signal Pads - RC-trigger circuits for a semiconductor controlled rectifier (SCR), methods of providing electrostatic discharge (ESD) protection, and design structures for a RC-trigger circuit. The RC-trigger circuit is coupled to an input/output (I/O) signal pad by an isolation diode and is coupled to a power supply voltage by a power supply diode. Under normal operating conditions, the isolation diode is reverse biased, isolating the RC-trigger circuit from the input/output (I/O) pad, and the power supply diode is forward biased so that the RC-trigger circuit is supplied with power. The isolation diode may become forward biased during ESD events while the chip is unpowered, causing the RC-trigger circuit to trigger an SCR configured protect the signal pad from ESD into a conductive state. The power supply diode may become reverse biased during the ESD event, which isolates the power supply rail from the ESD voltage pulse. | 10-11-2012 |
20120300349 | GATE DIELECTRIC BREAKDOWN PROTECTION DURING ESD EVENTS - Protection circuits, design structures, and methods for isolating the gate and gate dielectric of a field-effect transistor from electrostatic discharge (ESD). A protection field-effect transistor is located between a protected field-effect transistor and a voltage rail. Under normal operating conditions, the protection field-effect transistor is saturated so that the protected field-effect transistor is coupled to the voltage rail. The protection field-effect transistor may be driven into a cutoff condition in response to an ESD event while the chip is unpowered, which increases the series resistance of an ESD current path between the gate of the protected field-effect transistor and the voltage rail. The voltage drop across the protection field-effect transistor may reduce the ESD stress on the gate dielectric of the protected field-effect transistor. Alternatively, the gate and source of an existing field-effect transistor are selectively coupled provide ESD isolation to the protected field-effect transistor. | 11-29-2012 |
20130001589 | LATERAL EXTENDED DRAIN METAL OXIDE SEMICONDUCTOR FIELD EFFECT TRANSISTOR (LEDMOSFET) WITH TAPERED DIELECTRIC PLATES TO ACHIEVE A HIGH DRAIN-TO-BODY BREAKDOWN VOLTAGE, A METHOD OF FORMING THE TRANSISTOR AND A PROGRAM STORAGE DEVICE FOR DESIGNING THE TRANSISTOR - A lateral, extended drain, metal oxide semiconductor, field effect transistor (LEDMOSFET) with a high drain-to-body breakdown voltage (Vb) incorporates gate structure extensions on opposing sides of a drain drift region. The extensions are tapered such that a distance between each extension and the drift region increases linearly from one end adjacent to the channel region to another end adjacent to the drain region. In one embodiment, these extensions can extend vertically through the isolation region that surrounds the LEDMOSFET. In another embodiment, the extensions can sit atop the isolation region. In either case, the extensions create a strong essentially uniform horizontal electric field profile within the drain drift. Also disclosed are a method for forming the LEDMOSFET with a specific Vb by defining the dimensions of the extensions and a program storage device for designing the LEDMOSFET to have a specific Vb. | 01-03-2013 |
20130134557 | METAL-INSULATOR-METAL CAPACITORS WITH HIGH CAPACITANCE DENSITY - Metal-insulator-metal (MIM) capacitors and methods for fabricating MIM capacitors. The MIM capacitor includes an interlayer dielectric (ILD) layer with apertures each bounded by a plurality of sidewalls and each extending from the top surface of the ILD layer into the first interlayer dielectric layer. A layer stack, which is disposed on the sidewalls of the apertures and the top surface of the ILD layer, includes a bottom conductive electrode, a top conductive electrode, and a capacitor dielectric between the bottom and top conductive electrodes. | 05-30-2013 |
20130161687 | BI-DIRECTIONAL BACK-TO-BACK STACKED SCR FOR HIGH-VOLTAGE PIN ESD PROTECTION, METHODS OF MANUFACTURE AND DESIGN STRUCTURES - Bi-directional back-to-back stacked SCRs for high-voltage pin ESD protection, methods of manufacture and design structures are provided. The device includes a symmetrical bi-directional back-to-back stacked silicon controlled rectifier (SCR). An anode of a first of the back-to-back stacked SCR is connected to an input. An anode of a second of the back-to-back stacked SCR is connected to ground. Cathodes of the first and second of the back-to-back stacked SCR are connected together. Each of the symmetrical bi-directional back-to-back SCRs include a pair of diodes directing current towards the cathodes which, upon application of a voltage, become reverse biased effectively and deactivating elements from one of the symmetrical bi-directional back-to-back SCRs while the diodes of another of the symmetrical bi-directional back-to-back SCRs direct current in the same direction as the reverse biased diodes. | 06-27-2013 |
20140033519 | THROUGH SILICON VIA REPAIR - Methods and systems for altering the electrical resistance of a wiring path. The electrical resistance of the wiring path is compared with a target electrical resistance value. If the electrical resistance of the wiring path exceeds the target electrical resistance value, an electrical current is selectively applied to the wiring path to physically alter a portion of the wiring path. The current may be selected to alter the wiring path such that the electrical resistance drops to a value less than or equal to the target electrical resistance value. | 02-06-2014 |
20140042587 | SEMICONDUCTOR-ON-INSULATOR DEVICE WITH ASYMMETRIC STRUCTURE - Device structures with a reduced junction area in an SOI process, methods of making the device structures, and design structures for a lateral diode. The device structure includes one or more dielectric regions, such as STI regions, positioned in the device region and intersecting the p-n junction between an anode and cathode. The dielectric regions, which may be formed using shallow trench isolation techniques, function to reduce the width of a p-n junction with respect to the width area of the cathode at a location spaced laterally from the p-n junction and the anode. The width difference and presence of the dielectric regions creates an asymmetrical diode structure. The volume of the device region occupied by the dielectric regions is minimized to preserve the volume of the cathode and anode. | 02-13-2014 |
20140117452 | SEMICONDUCTOR STRUCTURES WITH THINNED JUNCTIONS AND METHODS OF MANUFACTURE - A method of forming a semiconductor structure, including forming a channel in a first portion of a semiconductor layer and forming a doped extension region in a second portion of the semiconductor layer abutting the channel on a first side and abutting an insulator material on a bottom side. The first portion of the semiconductor layer is thicker than the second portion of the semiconductor layer. | 05-01-2014 |
20140124903 | STRUCTURES, METHODS AND APPLICATIONS FOR ELECTRICAL PULSE ANNEAL PROCESSES - Structures and methods are provided for nanosecond electrical pulse anneal processes. The method of forming an electrostatic discharge (ESD) N+/P+ structure includes forming an N+ diffusion on a substrate and a P+ diffusion on the substrate. The P+ diffusion is in electrical contact with the N+ diffusion. The method further includes forming a device between the N+ diffusion and the P+ diffusion. A method of annealing a structure or material includes applying an electrical pulse across an electrostatic discharge (ESD) N+/P+ structure for a plurality of nanoseconds. | 05-08-2014 |
20150048416 | SILICON CONTROLLED RECTIFIERS (SCR), METHODS OF MANUFACTURE AND DESIGN STRUCTURES - Silicon controlled rectifiers (SCR), methods of manufacture and design structures are disclosed herein. The method includes forming a common P-well on a buried insulator layer of a silicon on insulator (SOI) wafer. The method further includes forming a plurality of silicon controlled rectifiers (SCR) in the P-well such that N+ diffusion cathodes of each of the plurality of SCRs are coupled together by the common P-well. | 02-19-2015 |