Patent application number | Description | Published |
20090244954 | STRUCTURE AND METHOD FOR IMPROVING STORAGE LATCH SUSCEPTIBILITY TO SINGLE EVENT UPSETS - A digital logic storage structure includes cross coupled first and second complementary metal oxide semiconductor (CMOS) inverters formed on a semiconductor substrate, the CMOS inverters including a first storage node and a second storage node that is the logical complement of the first storage node; both of the first and second storage nodes each selectively coupled to a deep trench capacitor through a switching transistor, with the switching transistors controlled by a common capacitance switch line coupled to gate conductors thereof; wherein, in a first mode of operation, the switching transistors are rendered nonconductive so as to isolate the deep trench capacitors from the inverter storage nodes and, in a second mode of operation, the switching transistors are rendered conductive so as to couple the deep trench capacitors to their respective storage nodes, thereby providing increased resistance of the storage nodes to single event upsets (SEUs). | 10-01-2009 |
20110163365 | STRUCTURE AND METHOD FOR IMPROVING STORAGE LATCH SUSCEPTIBILITY TO SINGLE EVENT UPSETS - A digital logic storage structure includes cross coupled first and second complementary metal oxide semiconductor (CMOS) inverters formed on a semiconductor substrate, the CMOS inverters including a first storage node and a second storage node that is the logical complement of the first storage node; both of the first and second storage nodes each selectively coupled to a deep trench capacitor through a switching transistor, with the switching transistors controlled by a common capacitance switch line coupled to gate conductors thereof; wherein, in a first mode of operation, the switching transistors are rendered nonconductive so as to isolate the deep trench capacitors from the inverter storage nodes and, in a second mode of operation, the switching transistors are rendered conductive so as to couple the deep trench capacitors to their respective storage nodes, thereby providing increased resistance of the storage nodes to single event upsets (SEUs). | 07-07-2011 |
20130020615 | Borderless Contacts in Semiconductor Devices - A method includes depositing a dummy fill material over exposed portions of a substrate and a gate stack disposed on the substrate, removing portions of the dummy fill material to expose portions of the substrate, forming a layer of spacer material over the exposed portions of the substrate, the dummy fill material and the gate stack, removing portions of the layer of spacer material to expose portions of the substrate and the dummy fill material, depositing a dielectric layer over the exposed portions of the spacer material, the substrate, and the gate stack, removing portions of the dielectric layer to expose portions of the spacer material, removing exposed portions of the spacer material to expose portions of the substrate and define at least one cavity in the dielectric layer, and depositing a conductive material in the at least one cavity. | 01-24-2013 |
Patent application number | Description | Published |
20110018093 | PROGRAMMABLE ANTI-FUSE STRUCTURE WITH DLC DIELECTRIC LAYER - In one embodiment an anti-fuse structure is provided that includes a first dielectric material having at least a first anti-fuse region and a second anti-fuse region, wherein at least one of the anti-fuse regions includes a conductive region embedded within the first dielectric material. The anti-fuse structure further includes a first diamond like carbon layer having a first conductivity located on at least the first dielectric material in the first anti-fuse region and a second diamond like carbon layer having a second conductivity located on at least the first dielectric material in the second anti-fuse region. In this embodiment, the second conductivity is different from the first conductivity and the first diamond like carbon layer and the second diamond like carbon layer have the same thickness. The anti-fuse structure also includes a second dielectric material located atop the first and second diamond like carbon layers. The second dielectric material includes at least one conductively filled region embedded therein. | 01-27-2011 |
20110081765 | METHOD TO IMPROVE WET ETCH BUDGET IN FEOL INTEGRATION - A method of forming a semiconductor device is provided where in one embodiment an STI fill is recessed below the pad nitride and pad oxide layers, to a level substantially coplanar with the top surface of the substrate. A thin (having a thickness in the range of about 10 Å-100 Å) wet etch resistant layer is formed in contact with and completely covering at least the top surface of the recessed STI fill material. The thin wet etch resistant layer is more resistant to a wet etch process than at least the pad oxide layer. The thin wet etch resistant layer may be a refractory dielectric material, or a dielectric such as HfO | 04-07-2011 |
20110272812 | STRUCTURE AND METHOD FOR MANUFACTURING INTERCONNECT STRUCTURES HAVING SELF-ALIGNED DIELECTRIC CAPS - Interconnect structures having self-aligned dielectric caps are provided. At least one metallization level is formed on a substrate. A dielectric cap is selectively deposited on the metallization level. | 11-10-2011 |
20120068346 | STRUCTURE FOR NANO-SCALE METALLIZATION AND METHOD FOR FABRICATING SAME - A method for forming structure aligned with features underlying an opaque layer is provided for an interconnect structure, such as an integrated circuit. In one embodiment, the method includes forming an opaque layer over a first layer, the first layer having a surface topography that maps to at least one feature therein, wherein the opaque layer is formed such that the surface topography is visible over the opaque layer. A second feature is positioned and formed in the opaque layer by reference to such surface topography. | 03-22-2012 |
20120178236 | METHOD TO IMPROVE WET ETCH BUDGET IN FEOL INTEGRATION - A method of forming a semiconductor device is provided where in one embodiment an STI fill is recessed below the pad nitride and pad oxide layers, to a level substantially coplanar with the top surface of the substrate. A thin (having a thickness in the range of about 10 Å-100 Å) wet etch resistant layer is formed in contact with and completely covering at least the top surface of the recessed STI fill material. The thin wet etch resistant layer is more resistant to a wet etch process than at least the pad oxide layer. The thin wet etch resistant layer may be a refractory dielectric material, or a dielectric such as HfO | 07-12-2012 |
20130115767 | Metal Alloy Cap Integration - A metal interconnect structure, which includes metal alloy capping layers, and a method of manufacturing the same. The originally deposited alloy capping layer element within the interconnect features will diffuse into and segregate onto top surface of the metal interconnect. The metal alloy capping material is deposited on a reflowed copper surface and is not physically in contact with sidewalls of the interconnect features. The metal alloy capping layer is also reflowed on the copper. Thus, there is a reduction in electrical resistivity impact from residual alloy elements in the interconnect structure. That is, there is a reduction, of alloy elements inside the features of the metal interconnect structure. The metal interconnect structure includes a dielectric layer with a recessed line, a liner material on sidewalls, a copper material, an alloy capping layer, and a dielectric cap. | 05-09-2013 |
20130193579 | STRUCTURE FOR NANO-SCALE METALLIZATION AND METHOD FOR FABRICATING SAME - A method for forming structure aligned with features underlying an opaque layer is provided for an interconnect structure, such as an integrated circuit. In one embodiment, the method includes forming an opaque layer over a first layer, the first layer having a surface topography that maps to at least one feature therein, wherein the opaque layer is formed such that the surface topography is visible over the opaque layer. A second feature is positioned and formed in the opaque layer by reference to such surface topography. | 08-01-2013 |
20130252419 | Metal Alloy Cap Integration - A metal interconnect structure, which includes metal alloy capping layers, and a method of manufacturing the same. The originally deposited alloy capping layer element within the interconnect features will diffuse into and segregate onto top surface of the metal interconnect. The metal alloy capping material is deposited on a reflowed copper surface and is not physically in contact with sidewalls of the interconnect features. The metal alloy capping layer is also reflowed on the copper. Thus, there is a reduction in electrical resistivity impact from residual alloy elements in the interconnect structure. That is, there is a reduction, of alloy elements inside the features of the metal interconnect structure. The metal interconnect structure includes a dielectric layer with a recessed line, a liner material on sidewalls, a copper material, an alloy capping layer, and a dielectric cap. | 09-26-2013 |
20140099792 | SINGLE FIN CUT EMPLOYING ANGLED PROCESSING METHODS - Fin-defining spacers are formed on an array of mandrel structure. Mask material portions can be directionally deposited on fin-defining spacers located on one side of each mandrel structure, while not deposited on the other side. A photoresist layer is subsequently applied and patterned to form an opening, of which the overlay tolerance increases by a pitch of fin-defining spacers due to the mask material portions. Alternately, a conformal silicon oxide layer can be deposited on fin-defining spacers and structure-damaging ion implantation is performed only on fin-defining spacers located on one side of each mandrel structure. A photoresist layer is subsequently applied and patterned to form an opening, from which a damaged silicon oxide portion and an underlying fin-defining spacer are removed, while undamaged silicon oxide portions are not removed. An array of semiconductor fins including a vacancy can be formed by transferring the pattern into a semiconductor layer. | 04-10-2014 |
Patent application number | Description | Published |
20110092860 | SYSTEM FOR CLINICAL ASSESSMENT OF MOVEMENT DISORDERS - According to one embodiment of the present invention, the system for clinical assessment of movement disorders (iTUG) is comprised of a) a protocol to assess gait, balance, and mobility; b) a plurality of wearable sensors including accelerometers, gyroscopes, magnetometers, optical sensors, and goniometers to record kinematics data obtained from a patient during said protocol; c) means for wirelessly transmitting said kinematics data to a storage and data processing server; and d) a plurality of statistical and biomedical signal processing methods to analyze said kinematic data and derive a plurality of metrics (outcomes) to objectively quantify movement disorders. A specially important outcome for the assessment of movement disorders is described, namely, the quantification of the onset and offset parameters during turning. A method for quantification of said onset and offset turning parameters involves 1) collecting data to measure the angle of the trunk during turning, 2) modeling said angle using a mathematical model, and 3) using numerical optimization and estimation methods for fitting the model in the data to determine said onset and offset turning parameters. | 04-21-2011 |
20110213278 | MOVEMENT MONITORING SYSTEM AND APPARATUS FOR OBJECTIVE ASSESSMENT OF MOVEMENT DISORDERS - Disclosed embodiments include a movement monitoring system and apparatus for objective assessment of movement disorders of a subject, comprising (a) one or more movement monitors, and (b) a computer-implemented analysis system comprising one or more protocols and associated data analysis methods to objectively quantify movement disorders based on movement data acquired by the movement monitors. According to one embodiment, the movement monitors are robust wireless synchronized movement monitors and the protocols include one or more tests for assessment of neural control of balance. | 09-01-2011 |