Patent application number | Description | Published |
20090283840 | METAL GATE INTEGRATION STRUCTURE AND METHOD INCLUDING METAL FUSE, ANTI-FUSE AND/OR RESISTOR - A semiconductor structure and a method for fabricating the semiconductor structure provide a field effect device located and formed upon an active region of a semiconductor substrate and at least one of a fuse structure, an anti-fuse structure and a resistor structure located and formed at least in part simultaneously upon an isolation region laterally separated from the active region within the semiconductor substrate. The field effect device includes a gate dielectric comprising a high dielectric constant dielectric material and a gate electrode comprising a metal material. The at least one of the fuse structure, anti-fuse structure and resistor structure includes a pad dielectric comprising the same material as the gate dielectric, and optionally, also a fuse, anti-fuse or resistor that may comprise the same metal material as the gate electrode. | 11-19-2009 |
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 |
20120091556 | VERTICAL SILICIDE E-FUSE - An apparatus and a method of manufacturing an e-fuse includes a substrate, a patterned gate insulator on the substrate, and a patterned gate conductor on the patterned gate insulator. The patterned gate conductor has sidewalls and a top. A silicide contacts the sidewalls of the patterned gate conductor, the top of the patterned gate conductor, and a region of the substrate adjacent the patterned gate insulator and the patterned gate conductor. | 04-19-2012 |
20120306014 | STRESS ENHANCED LDMOS TRANSISTOR TO MINIMIZE ON-RESISTANCE AND MAINTAIN HIGH BREAKDOWN VOLTAGE - A lateral diffused metal-oxide-semiconductor field effect transistor (LDMOS transistor) employs a stress layer that enhances carrier mobility (i.e., on-current) while also maintaining a high breakdown voltage for the device. High breakdown voltage is maintained, because an increase in doping concentration of the drift region is minimized. A well region and a drift region are formed in the substrate adjacent to one another. A first shallow trench isolation (STI) region is formed on and adjacent to the well region, and a second STI region is formed on and adjacent to the drift region. A stress layer is deposited over the LDMOS transistor and in the second STI region, which propagates compressive or tensile stress into the drift region, depending on the polarity of the stress layer. A portion of the stress layer can be removed over the gate to change the polarity of stress in the inversion region below the gate. | 12-06-2012 |
20120326766 | Silicon Controlled Rectifier with Stress-Enhanced Adjustable Trigger Voltage - Device structures, fabrication methods, operating methods, and design structures for a silicon controlled rectifier. The method includes applying a mechanical stress to a region of a silicon controlled rectifier (SCR) at a level sufficient to modulate a trigger current of the SCR. The device and design structures include a SCR with an anode, a cathode, a first region, and a second region of opposite conductivity type to the first region. The first and second regions of the SCR are disposed in a current-carrying path between the anode and cathode of the SCR. A layer is positioned on a top surface of a semiconductor substrate relative to the first region and configured to cause a mechanical stress in the first region of the SCR at a level sufficient to modulate a trigger current of the SCR. | 12-27-2012 |
20130313607 | Silicon Controlled Rectifier With Stress-Enhanced Adjustable Trigger Voltage - Device structures, fabrication methods, operating methods, and design structures for a silicon controlled rectifier. The method includes applying a mechanical stress to a region of a silicon controlled rectifier (SCR) at a level sufficient to modulate a trigger current of the SCR. The device and design structures include a SCR with an anode, a cathode, a first region, and a second region of opposite conductivity type to the first region. The first and second regions of the SCR are disposed in a current-carrying path between the anode and cathode of the SCR. A layer is positioned on a top surface of a semiconductor substrate relative to the first region and configured to cause a mechanical stress in the first region of the SCR at a level sufficient to modulate a trigger current of the SCR. | 11-28-2013 |
20140030861 | STRESS ENHANCED LDMOS TRANSISTOR TO MINIMIZE ON-RESISTANCE AND MAINTAIN HIGH BREAKDOWN VOLTAGE - A lateral diffused metal-oxide-semiconductor field effect transistor (LDMOS transistor) employs a stress layer that enhances carrier mobility (i.e., on-current) while also maintaining a high breakdown voltage for the device. High breakdown voltage is maintained, because an increase in doping concentration of the drift region is minimized A well region and a drift region are formed in the substrate adjacent to one another. A first shallow trench isolation (STI) region is formed on and adjacent to the well region, and a second STI region is formed on and adjacent to the drift region. A stress layer is deposited over the LDMOS transistor and in the second STI region, which propagates compressive or tensile stress into the drift region, depending on the polarity of the stress layer. A portion of the stress layer can be removed over the gate to change the polarity of stress in the inversion region below the gate. | 01-30-2014 |
Patent application number | Description | Published |
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 |
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 |
20090230475 | FIELD EFFECT STRUCTURE INCLUDING CARBON ALLOYED CHANNEL REGION AND SOURCE/DRAIN REGION NOT CARBON ALLOYED - A semiconductor structure and a method for fabricating the semiconductor structure provide a field effect device structure. The field effect device structure includes a gate electrode located over a channel region within a semiconductor substrate that separates a plurality of source and drain regions within the semiconductor substrate. The channel region includes a surface layer that comprises a carbon doped semiconductor material. The source and drain regions include a surface layer that comprises a semiconductor material that is not carbon doped. The particular selection of material for the channel region and source and drain regions provide for inhibited dopant diffusion and enhanced mechanical stress within the channel region, and thus enhanced performance of the field effect device. | 09-17-2009 |