Patent application number | Description | Published |
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 |
20080203522 | Structure Incorporating Latch-Up Resistant Semiconductor Device Structures on Hybrid Substrates - Device structure embodied in a machine readable medium for designing, manufacturing, or testing a design in which the design structure includes latch-up resistant devices formed on a hybrid substrate. The hybrid substrate is characterized by first and second semiconductor regions that are formed on a bulk semiconductor region. The second semiconductor region is separated from the bulk semiconductor region by an insulating layer. The first semiconductor region is separated from the bulk semiconductor region by a conductive region of an opposite conductivity type from the bulk semiconductor region. The buried conductive region thereby the susceptibility of devices built using the first semiconductor region to latch-up. | 08-28-2008 |
20080206978 | ELECTRONIC FUSES IN SEMICONDUCTOR INTEGRATED CIRCUITS - A structure fabrication method. The method includes providing a structure. The structure includes (a) a substrate layer, (b) a first fuse electrode in the substrate layer, and (c) a fuse dielectric layer on the substrate layer and the first fuse electrode. The method further includes (i) forming an opening in the fuse dielectric layer such that the first fuse electrode is exposed to a surrounding ambient through the opening, (ii) forming a fuse region on side walls and bottom walls of the opening such that the fuse region is electrically coupled to the first fuse electrode, and (iii) after said forming the fuse region, filling the opening with a dielectric material. | 08-28-2008 |
20080211054 | METHODS FOR FORMING GERMANIUM-ON-INSULATOR SEMICONDUCTOR STRUCTURES USING A POROUS LAYER AND SEMICONDUCTOR STRUCTURES FORMED BY THESE METHODS - A semiconductor structure that includes a monocrystalline germanium-containing layer, preferably substantially pure germanium, a substrate, and a buried insulator layer separating the germanium-containing layer from the substrate. A porous layer, which may be porous silicon, is formed on a substrate and a germanium-containing layer is formed on the porous silicon layer. The porous layer may be converted to a layer of oxide, which provides the buried insulator layer. Alternatively, the germanium-containing layer may be transferred from the porous layer to an insulating layer on another substrate. After the transfer, the insulating layer is buried between the latter substrate and the germanium-containing layer. | 09-04-2008 |
20080217671 | METHODS FOR FORMING SEMICONDUCTOR STRUCTURES WITH BURIED ISOLATION COLLARS AND SEMICONDUCTOR STRUCTURES FORMED BY THESE METHODS - A semiconductor structure including a trench formed in a substrate and a buried isolation collar that extends about sidewalls of the trench. The buried isolation collar is constituted by an insulator formed from a buried porous region of substrate material. The porous region is formed from a buried doped region defined using masking and ion implantation or by masking the trench sidewalls and using dopant diffusion. Advantageously, the porous region is transformed to an oxide insulator by an oxidation process. The semiconductor structure may be a storage capacitor of a memory cell further having a buried plate about the trench and a capacitor node inside the trench that is separated from the buried plate by a node dielectric formed on the trench sidewalls. | 09-11-2008 |
20080217690 | Latch-Up Resistant Semiconductor Structures on Hybrid Substrates and Methods for Forming Such Semiconductor Structures - Latch-up resistant semiconductor structures formed on a hybrid substrate and methods of forming such latch-up resistant semiconductor structures. The hybrid substrate is characterized by first and second semiconductor regions that are formed on a bulk semiconductor region. The second semiconductor region is separated from the bulk semiconductor region by an insulating layer. The first semiconductor region is separated from the bulk semiconductor region by a conductive region of an opposite conductivity type from the bulk semiconductor region. The buried conductive region thereby the susceptibility of devices built using the first semiconductor region to latch-up. | 09-11-2008 |
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 |
20080220583 | SEMICONDUCTOR DEVICE STRUCTURES FOR BIPOLAR JUNCTION TRANSISTORS AND METHODS OF FABRICATING SUCH STRUCTURES - Semiconductor device structures for use with bipolar junction transistors and methods of fabricating such semiconductor device structures. The semiconductor device structure comprises a semiconductor body having a top surface and sidewalls extending from the top surface to an insulating layer, a first region including a first semiconductor material with a first conductivity type, and a second region including a second semiconductor material with a second conductivity type. The first and second regions each extend across the top surface and the sidewalls of the semiconductor body. The device structure further comprises a junction defined between the first and second regions and extending across the top surface and the sidewalls of the semiconductor body. | 09-11-2008 |
20080220586 | METHODS FOR FORMING SEMICONDUCTOR STRUCTURES WITH BURIED ISOLATION COLLARS AND SEMICONDUCTOR STRUCTURES FORMED BY THESE METHODS - A semiconductor structure including a trench formed in a substrate and a buried isolation collar that extends about sidewalls of the trench. The buried isolation collar is constituted by an insulator formed from a buried porous region of substrate material. The porous region is formed from a buried doped region defined using masking and ion implantation or by masking the trench sidewalls and using dopant diffusion. Advantageously, the porous region is transformed to an oxide insulator by an oxidation process. The semiconductor structure may be a storage capacitor of a memory cell further having a buried plate about the trench and a capacitor node inside the trench that is separated from the buried plate by a node dielectric formed on the trench sidewalls. | 09-11-2008 |
20080224175 | SEMICONDUCTOR DEVICE STRUCTURES FOR BIPOLAR JUNCTION TRANSISTORS AND METHODS OF FABRICATING SUCH STRUCTURES - Semiconductor device structures for use with bipolar junction transistors and methods of fabricating such semiconductor device structures. The semiconductor device structure includes a semiconductor body having a top surface and sidewalls extending from the top surface to an insulating layer, a first region including a first semiconductor material with a first conductivity type, and a second region including a second semiconductor material with a second conductivity type. The first and second regions each extend across the top surface and the sidewalls of the semiconductor body. The device structure further includes a junction defined between the first and second regions and extending across the top surface and the sidewalls of the semiconductor body. | 09-18-2008 |
20080224261 | Fuse/anti-fuse structure and methods of making and programming same - Techniques are provided for fuse/anti-fuse structures, including an inner conductor structure, an insulating layer spaced outwardly of the inner conductor structure, an outer conductor structure disposed outwardly of the insulating layer, and a cavity-defining structure that defines a cavity, with at least a portion of the cavity-defining structure being formed from at least one of the inner conductor structure, the insulating layer, and the outer conductor stricture Methods of making and programming the fuse/anti-fuse structures are also provided. | 09-18-2008 |
20080227425 | APPARATUS FOR IMPLEMENTING ENHANCED HAND SHAKE PROTOCOL IN MICROELECTRONIC COMMUNICATION SYSTEMS - A method and apparatus are provided for implementing an enhanced hand shake protocol for microelectronic communication systems. A transmitter and a receiver is coupled together by a transmission link. The transmitter receives an idle input. The idle input is activated when the transmitter is not transmitting data and the transmitter applies a first common mode level to the receiving unit. The idle input is deactivated when the transmitter is ready to transmit data and the transmitter raises the common mode level to the receiving unit. Responsive to the receiver detecting the common mode level up-movement, then the receiver receives the transmitted data signals. After the desired data has been sent, the transmitter terminates communications, drops the common mode level with the idle input being activated. | 09-18-2008 |
20080233699 | BULK FinFET DEVICE - A finFET structure and a method of fabricating the finFET structure. The method includes: forming a silicon fin on a top surface of a silicon substrate; forming a gate dielectric on opposite sidewalls of the fin; forming a gate electrode over a channel region of the fin, the gate electrode in direct physical contact with the gate dielectric layer on the opposite sidewalls of the fin; forming a first source/drain in the fin on a first side of the channel region and forming a second source/drain in the fin on a second side of the channel region; removing a portion of the substrate from under at least a portion of the first and second source/drains to create a void; and filling the void with a dielectric material. The structure includes a body contact between the silicon body of the finFET and the substrate. | 09-25-2008 |
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 |
20080251878 | STRUCTURE INCORPORATING SEMICONDUCTOR DEVICE STRUCTURES FOR USE IN SRAM DEVICES - Device structures embodied in a machine readable medium for designing, manufacturing, or testing a design in which the design structure includes static random access memory (SRAM) devices. The design structure includes a dielectric region disposed between first and second semiconductor regions and a gate conductor structure extending between the first and second semiconductor regions. The gate conductor structure has a first sidewall overlying the first semiconductor region. The design structure further comprises an electrically connective bridge extending across the first semiconductor region. A portion of the electrically connective bridge electrically connects a impurity-doped region in the first semiconductor region with the first sidewall of the gate conductor structure. | 10-16-2008 |
20080251934 | Semiconductor Device Structures and Methods of Fabricating Semiconductor Device Structures for Use in SRAM Devices - Semiconductor device structures and methods of fabricating such semiconductor device structures for use in static random access memory (SRAM) devices. The semiconductor device structure comprises a dielectric region disposed between first and second semiconductor regions and a gate conductor structure extending between the first and second semiconductor regions. The gate conductor structure has a first sidewall overlying the first semiconductor region. The device structure further comprises an electrically connective bridge extending across the first semiconductor region. The electrically connective bridge has a portion that electrically connects a impurity-doped region in the first semiconductor region with the first sidewall of the gate conductor structure. | 10-16-2008 |
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 |
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 |
20080272412 | METHOD AND STRUCTURE TO REDUCE CONTACT RESISTANCE ON THIN SILICON-ON-INSULATOR DEVICE - A method (and system) of reducing contact resistance on a silicon-on-insulator device, including controlling a silicide depth in a source-drain region of the device. | 11-06-2008 |
20080274597 | METHOD AND STRUCTURE TO REDUCE CONTACT RESISTANCE ON THIN SILICON-ON-INSULATOR DEVICE - A method (and system) of reducing contact resistance on a silicon-on-insulator device, including controlling a silicide depth in a source-drain region of the device. | 11-06-2008 |
20080283917 | METHODS FOR FABRICATING A SEMICONDUCTOR STRUCTURE USING A MANDREL AND SEMICONDUCTOR STRUCTURES FORMED THEREBY - Methods of fabricating a semiconductor structure in which a body of monocrystalline silicon is formed on a sidewall of a sacrificial mandrel and semiconductor structures made by the methods. After the body of monocrystalline silicon is formed, the sacrificial material of the mandrel is removed selective to the monocrystalline silicon of the body. The mandrel may be composed of porous silicon and the body may be fabricated using either a semiconductor-on-insulator substrate or a bulk substrate. The body may be used to fabricate a fin body of a fin-type field effect transistor. | 11-20-2008 |
20080283920 | HYBRID ORIENTED SUBSTRATES AND CRYSTAL IMPRINTING METHODS FOR FORMING SUCH HYBRID ORIENTED SUBSTRATES - A semiconductor structure with an insulating layer on a silicon substrate, a plurality of electrically-isolated silicon-on-insulator (SOI) regions separated from the substrate by the insulating layer, and a plurality of electrically-isolated silicon bulk regions extending through the insulating layer to the substrate. Each of one number of the SOI regions is oriented with a first crystal orientation and each of another number of the SOI regions is oriented with a second crystal orientation that differs from the first crystal orientation. The bulk silicon regions are each oriented with a third crystal orientation. Damascene or imprinting methods of forming the SOI regions and bulk silicon regions are also provided. | 11-20-2008 |
20090001426 | Integrated Fin-Local Interconnect Structure - Embodiments of the invention generally relate to semiconductor devices, and more specifically to interconnecting semiconductor devices. A silicide layer may be formed on selective areas of a fin structure connecting one or more semiconductor devices or semiconductor device components. By providing silicided fin structures to locally interconnect semiconductor devices, the use of metal contacts and metal layers may be obviated, thereby allowing formation of smaller, less complex circuits. | 01-01-2009 |
20090001477 | Hybrid Fully-Silicided (FUSI)/Partially-Silicided (PASI) Structures - Embodiments of the invention generally relate to semiconductor devices and more specifically to forming partially silicided and fully silicided structures. Fabricating the partially silicided and fully silicided structures may involve creating one or more gate stacks. A polysilicon layer of a first gate stack may be exposed and a first metal layer may be deposited thereon to create a partially silicided structure. Thereafter, a polysilicon layer of a second gate stack may be exposed and a second metal layer may be deposited thereon to form a fully silicided structure. In some embodiments, the polysilicon layers of one or more gate stacks may not be exposed, and resistors may be formed with the unsilicided polysilicon layers. | 01-01-2009 |
20090007036 | Integrated Fin-Local Interconnect Structure - Embodiments of the invention generally relate to methods, systems and design structures for semiconductor devices, and more specifically to interconnecting semiconductor devices. A silicide layer may be formed on selective areas of a fin structure connecting one or more semiconductor devices or semiconductor device components. By providing silicided fin structures to locally interconnect semiconductor devices, the use of metal contacts and metal layers may be obviated, thereby allowing formation of smaller, less complex circuits. | 01-01-2009 |
20090007037 | Hybrid Fully-Silicided (FUSI)/Partially-Silicided (PASI) Structures - Embodiments of the invention generally relate to methods, systems and design structures for semiconductor devices and more specifically to forming partially silicided and fully silicided structures. Fabricating the partially silicided and fully silicided structures may involve creating one or more gate stacks. A polysilicon layer of a first gate stack may be exposed and a first metal layer may be deposited thereon to create a partially silicided structure. Thereafter, a polysilicon layer of a second gate stack may be exposed and a second metal layer may be deposited thereon to form a fully silicided structure. In some embodiments, the polysilicon layers of one or more gate stacks may not be exposed, and resistors may be formed with the unsilicided polysilicon layers. | 01-01-2009 |
20090121312 | METHOD AND APPARATUS FOR MAKING COPLANAR ISOLATED REGIONS OF DIFFERENT SEMICONDUCTOR MATERIALS ON A SUBSTRATE - A semiconductor processing method includes providing a substrate, forming a plurality of semiconductor layers in the substrate, each of the semiconductor layers being distinct and selected from different groups of semiconductor element types. The semiconductor layers include a first, second, and third semiconductor layers. The method further includes forming a plurality of lateral void gap isolation regions for isolating portions of each of the semiconductor layers from portions of the other semiconductor layers. | 05-14-2009 |
20100320563 | ELECTRONIC FUSES IN SEMICONDUCTOR INTEGRATED CIRCUITS - A structure. The structure includes: a substrate; a first electrode in the substrate; a dielectric layer on top of the substrate and the electrode; a second dielectric layer on the first dielectric layer, said second dielectric layer comprising a second dielectric material; a fuse element buried in the first dielectric layer, wherein the fuse element (i) physically separates, (ii) is in direct physical contact with both, and (iii) is sandwiched between a first region and a second region of the dielectric layer; and a second electrode on top of the fuse element, wherein the first electrode and the second electrode are electrically coupled to each other through the fuse element. | 12-23-2010 |
20120248567 | LAYERED STRUCTURE WITH FUSE - A structure. The structure includes: a substrate, a first electrode in the substrate, first dielectric layer above both the substrate and the first electrode, a second dielectric layer above the first dielectric layer, and a fuse element buried in the first dielectric layer. The first electrode includes a first electrically conductive material. A top surface of the first dielectric layer is further from a top surface of the first electrode than is any other surface of the first dielectric layer. The first dielectric layer includes a first dielectric material and a second dielectric material. A bottom surface of the second dielectric layer is in direct physical contact with the top surface of the first dielectric layer. The second dielectric layer includes the second dielectric material. | 10-04-2012 |