Patent application number | Description | Published |
20080197448 | SHALLOW TRENCH ISOLATION FILL BY LIQUID PHASE DEPOSITION OF SiO2 - To isolate two active regions formed on a silicon-on-insulator (SOI) substrate, a shallow trench isolation region is filled with liquid phase deposited silicon dioxide (LPD-SiO | 08-21-2008 |
20080203492 | METHODS FOR FABRICATING SEMICONDUCTOR DEVICE STRUCTURES WITH REDUCED SUSCEPTIBILITY TO LATCH-UP AND SEMICONDUCTOR DEVICE STRUCTURES FORMED BY THE METHODS - Semiconductor methods and device structures for suppressing latch-up in bulk CMOS devices. The method comprises forming a trench in the semiconductor material of the substrate with first sidewalls disposed between a pair of doped wells, also defined in the semiconductor material of the substrate. The method further comprises forming an etch mask in the trench to partially mask the base of the trench, followed by removing the semiconductor material of the substrate exposed across the partially masked base to define narrowed second sidewalls that deepen the trench. The deepened trench is filled with a dielectric material to define a trench isolation region for devices built in the doped wells. The dielectric material filling the deepened extension of the trench enhances latch-up suppression. | 08-28-2008 |
20080206937 | WRAP-AROUND GATE FIELD EFFECT TRANSISTOR - A field effect transistor is formed having wrap-around, vertically-aligned, dual gate electrodes. Starting with a silicon-on-insulator (SOI) structure having a buried silicon island, a vertical reference edge is defined, by creating a cavity within the SOI structure, and used during two etch-back steps that can be reliably performed. The first etch-back removes a portion of an oxide layer for a first distance over which a gate conductor material is then applied. The second etch-back removes a portion of the gate conductor material for a second distance. The difference between the first and second distances defines the gate length of the eventual device. After stripping away the oxide layers, a vertical gate electrode is revealed that surrounds the buried silicon island on all four side surfaces. | 08-28-2008 |
20080206996 | SIDEWALL IMAGE TRANSFER PROCESSES FOR FORMING MULTIPLE LINE-WIDTHS - A method for simultaneously forming multiple line-widths, one of which is less than that achievable employing conventional lithographic techniques. The method includes providing a structure which includes a memory layer and a sidewall image transfer (SIT) layer on top of the memory layer. Then, the SIT layer is patterned resulting in a SIT region. Then, the SIT region is used as a blocking mask during directional etching of the memory layer resulting in a first memory region. Then, a side wall of the SIT region is retreated a retreating distance D in a reference direction resulting in a SIT portion. Said patterning comprises a lithographic process. The retreating distance D is less than a critical dimension CD associated with the lithographic process. The SIT region includes a first dimension W | 08-28-2008 |
20080217698 | METHODS AND SEMICONDUCTOR STRUCTURES FOR LATCH-UP SUPPRESSION USING A CONDUCTIVE REGION - Semiconductor structures and methods for suppressing latch-up in bulk CMOS devices. The semiconductor structure comprises first and second adjacent doped wells formed in the semiconductor material of a substrate. A trench, which includes a base and first sidewalls between the base and the top surface, is defined in the substrate between the first and second doped wells. The trench is partially filled with a conductor material that is electrically coupled with the first and second doped wells. Highly-doped conductive regions may be provided in the semiconductor material bordering the trench at a location adjacent to the conductive material in the trench. | 09-11-2008 |
20080227264 | VERTICAL NANOTUBE SEMICONDUCTOR DEVICE STRUCTURES AND METHODS OF FORMING THE SAME - Vertical device structures incorporating at least one nanotube and methods for fabricating such device structures by chemical vapor deposition. Each nanotube is grown by chemical vapor deposition catalyzed by a catalyst pad and encased in a coating of a dielectric material. Vertical field effect transistors may be fashioned by forming a gate electrode about the encased nanotubes such that the encased nanotubes extend vertically through the thickness of the gate electrode. Capacitors may be fashioned in which the encased nanotubes and the corresponding catalyst pad bearing the encased nanotubes forms one capacitor plate. | 09-18-2008 |
20080242016 | METHODS FOR FABRICATING SEMICONDUCTOR DEVICE STRUCTURES WITH REDUCED SUSCEPTIBILITY TO LATCH-UP AND SEMICONDUCTOR DEVICE STRUCTURES FORMED BY THE METHODS - Semiconductor methods and device structures for suppressing latch-up in bulk CMOS devices. The method comprises forming a trench in the semiconductor material of the substrate with first sidewalls disposed between a pair of doped wells, also defined in the semiconductor material of the substrate. The method further comprises forming an etch mask in the trench to partially mask the base of the trench, followed by removing the semiconductor material of the substrate exposed across the partially masked base to define narrowed second sidewalls that deepen the trench. The deepened trench is filled with a dielectric material to define a trench isolation region for devices built in the doped wells. The dielectric material filling the deepened extension of the trench enhances latch-up suppression. | 10-02-2008 |
20080245984 | MICRO-ELECTRO-MECHANICAL VALVES AND PUMPS AND METHODS OF FABRICATING SAME - Micro-valves and micro-pumps and methods of fabricating micro-valves and micro-pumps. The micro-valves and micro-pumps include electrically conductive diaphragms fabricated from electrically conductive nano-fibers. Fluid flow through the micro-valves and pumping action of the micro-pumps is accomplished by applying electrostatic forces to the electrically conductive diaphragms. | 10-09-2008 |
20080258181 | Hybrid Substrates and Methods for Forming Such Hybrid Substrates - Hybrid substrates characterized by semiconductor islands of different crystal orientations and methods of forming such hybrid substrates. The methods involve using a SIMOX process to form an insulating layer. The insulating layer may divide the islands of at least one of the different crystal orientations into mutually aligned device and body regions. The body regions may be electrically floating relative to the device regions. | 10-23-2008 |
20080258222 | Design Structure Incorporating a Hybrid Substrate - Design structure embodied in a machine readable medium for designing, manufacturing, or testing a design in which the design structure includes devices formed in a hybrid substrate characterized by semiconductor islands of different crystal orientations. An insulating layer divides the islands of at least one of the different crystal orientations into mutually aligned device and body regions. The body regions may be electrically floating relative to the device regions. | 10-23-2008 |
20080258246 | PASSIVE ELECTRICALLY TESTABLE ACCELERATION AND VOLTAGE MEASUREMENT DEVICES - Acceleration and voltage measurement devices and methods of fabricating acceleration and voltage measurement devices. The acceleration and voltage measurement devices including an electrically conductive plate on a top surface of a first insulating layer; a second insulating layer on a top surface of the conductive plate, the top surface of the plate exposed in an opening in the second insulating layer; conductive nanotubes suspended across the opening, and electrically conductive contacts to said nanotubes. | 10-23-2008 |
20080261363 | DUAL GATED FINFET GAIN CELL - A memory gain cell for a memory circuit, a memory circuit formed from multiple memory gain cells, and methods of fabricating such memory gain cells and memory circuits. The memory gain cell includes a storage device capable of holding a stored electrical charge, a write device, and a read device. The read device includes a fin of semiconducting material, electrically-isolated first and second gate electrodes flanking the fin, and a source and drain formed in the fin adjacent to the first and the second gate electrodes. The first gate electrode is electrically coupled with the storage device. The first and second gate electrodes are operative for gating a region of the fin defined between the source and the drain to thereby regulate a current flowing from the source to the drain. When gated, the magnitude of the current is dependent upon the electrical charge stored by the storage device. | 10-23-2008 |
20080268610 | METHODS AND SEMICONDUCTOR STRUCTURES FOR LATCH-UP SUPPRESSION USING A CONDUCTIVE REGION - Semiconductor structures and methods for suppressing latch-up in bulk CMOS devices. The semiconductor structure comprises first and second adjacent doped wells formed in the semiconductor material of a substrate. A trench, which includes a base and first sidewalls between the base and the top surface, is defined in the substrate between the first and second doped wells. The trench is partially filled with a conductor material that is electrically coupled with the first and second doped wells. Highly-doped conductive regions may be provided in the semiconductor material bordering the trench at a location adjacent to the conductive material in the trench. | 10-30-2008 |
20090001481 | DIGITAL CIRCUITS HAVING ADDITIONAL CAPACITORS FOR ADDITIONAL STABILITY - A semiconductor structure and a method for forming the same. The semiconductor structure includes (a) a semiconductor substrate, (b) a shallow trench isolation (STI) region on the semiconductor substrate, and (c) a first semiconductor transistor on the semiconductor substrate. The first semiconductor transistor includes (I) a first source/drain region, (ii) a second source/drain region, and (iii) a first gate electrode region. The first and second source/drain regions are doped with a same doping polarity. The semiconductor structure further includes a first doped region in the semiconductor substrate. The first doped region is on a first side wall and a bottom wall of the STI region. The first doped region is in direct physical contact with the second source/drain region. The first doped region and the second source/drain region are doped with a same doping polarity. | 01-01-2009 |
20090035708 | LAYER PATTERNING USING DOUBLE EXPOSURE PROCESSES IN A SINGLE PHOTORESIST LAYER - A structure and a method for forming the same. The method includes providing a structure which includes (a) a to-be-patterned layer, (b) a photoresist layer on top of the to-be-patterned layer wherein the photoresist layer includes a first opening, and (c) a cap region on side walls of the first opening. A first top surface of the to-be-patterned layer is exposed to a surrounding ambient through the first opening. The method further includes performing a first lithography process resulting in a second opening in the photoresist layer. The second opening is different from the first opening. A second top surface of the to-be-patterned layer is exposed to a surrounding ambient through the second opening. | 02-05-2009 |
20100176512 | STRUCTURE AND METHOD FOR BACK END OF THE LINE INTEGRATION - An improved semiconductor structure consists of interconnects in an upper interconnect level connected to interconnects in a lower interconnect level through use of a conductive protrusion located at the bottom of a via opening in an upper interconnect level, the conductive protrusion extends upward from bottom of the via opening and into the via opening. The improved interconnect structure with the conductive protrusion between the upper and lower interconnects enhances overall interconnect reliability. | 07-15-2010 |
20100273298 | Method of Making Integrated Circuit Chip Utilizing Oriented Carbon Nanotube Conductive Layers - A conductive layer in an integrated circuit is formed as a sandwich having multiple sublayers, including at least one sublayer of oriented carbon nanotubes. The conductive layer sandwich preferably contains two sublayers of carbon nanotubes, in which the carbon nanotube orientation in one sublayer is substantially perpendicular to that of the other layer. The conductive layer sandwich preferably contains one or more additional sublayers of a conductive material, such as a metal. In one embodiment, oriented carbon nanotubes are created by forming a series of elongated parallel catalyst strips on a horizontal surface, and growing carbon nanotubes from the catalyst in the presence of a directional flow of reactant gases. | 10-28-2010 |
20120012979 | SEMICONDUCTOR CAPACITOR - An improved semiconductor capacitor and method of fabrication is disclosed. A nitride stack, comprising alternating sublayers of slow-etch and fast-etch nitride is deposited on a substrate. The nitride stack is etched via an anisotropic etch technique such as reactive ion etch. A wet etch then etches the nitride stack, forming a corrugated shape. The corrugated shape increases surface area, and hence increases the capacitance of the capacitor. | 01-19-2012 |
20120012980 | SEMICONDUCTOR CAPACITOR - A semiconductor capacitor and its method of fabrication are disclosed. A non-linear nitride layer is used to increase the surface area of a capacitor plate, resulting in increased capacitance without increase in chip area used for the capacitor. | 01-19-2012 |
20130307087 | METHOD FOR FORMING A SELF-ALIGNED CONTACT OPENING BY A LATERAL ETCH - A self-aligned source/drain contact formation process without spacer or cap loss is described. Embodiments include providing two gate stacks, each having spacers on opposite sides, and an interlayer dielectric (ILD) over the two gate stacks and in a space therebetween, forming a vertical contact opening within the ILD between the two gate stacks, and laterally removing ILD between the two gate stacks from the vertical contact opening toward the spacers, to form a contact hole. | 11-21-2013 |
20140191296 | SELF-ALIGNED DIELECTRIC ISOLATION FOR FINFET DEVICES - Embodiments of the present invention provide a method of forming semiconductor structure. The method includes forming a set of device features on top of a substrate; forming a first dielectric layer directly on top of the set of device features and on top of the substrate, thereby creating a height profile of the first dielectric layer measured from a top surface of the substrate, the height profile being associated with a pattern of an insulating structure that fully surrounds the set of device features; and forming a second dielectric layer in areas that are defined by the pattern to create the insulating structure. A structure formed by the method is also disclosed. | 07-10-2014 |
20140191323 | METHOD OF FORMING FINFET OF VARIABLE CHANNEL WIDTH - Embodiments of present invention provide a method of forming a first and a second group of fins on a substrate; covering a top first portion of the first and second groups of fins with a first dielectric material; covering a bottom second portion of the first and second groups of fins with a second dielectric material, the bottom second portion of the first group and the second group of fins having a same height; exposing a middle third portion of the first and second groups of fins to an oxidizing environment to create an oxide section that separates the top first portion from the bottom second portion of the first and second groups of fins; and forming one or more fin-type field-effect-transistors (FinFETs) using the top first portion of the first and second groups of fins as fins under gates of the one or more FinFETs. | 07-10-2014 |
20150061040 | SELF-ALIGNED DIELECTRIC ISOLATION FOR FINFET DEVICES - Embodiments of the present invention provide a method of forming semiconductor structure. The method includes forming a set of device features on top of a substrate; forming a first dielectric layer directly on top of the set of device features and on top of the substrate, thereby creating a height profile of the first dielectric layer measured from a top surface of the substrate, the height profile being associated with a pattern of an insulating structure that fully surrounds the set of device features; and forming a second dielectric layer in areas that are defined by the pattern to create the insulating structure. A structure formed by the method is also disclosed. | 03-05-2015 |