Patent application number | Description | Published |
20080308940 | LATERAL CURRENT CARRYING CAPABILITY IMPROVEMENT IN SEMICONDUCTOR DEVICES - A semiconductor structure. The semiconductor structure includes (a) a substrate; (b) a first semiconductor device on the substrate; (c) N ILD (Inter-Level Dielectric) layers on the first semiconductor device, wherein N is an integer greater than one; and (d) an electrically conductive line electrically coupled to the first semiconductor device. The electrically conductive line is adapted to carry a lateral electric current in a lateral direction parallel to an interfacing surface between two consecutive ILD layers of the N ILD layers. The electrically conductive line is present in at least two ILD layers of the N ILD layers. The electrically conductive line does not comprise an electrically conductive via that is adapted to carry a vertical electric current in a vertical direction perpendicular to the interfacing surface. | 12-18-2008 |
20090106726 | DESIGN STRUCTURES INCLUDING MEANS FOR LATERAL CURRENT CARRYING CAPABILITY IMPROVEMENT IN SEMICONDUCTOR DEVICES - A design structure including a semiconductor structure. The semiconductor structure includes (a) a substrate; (b) a first semiconductor device on the substrate; (c) N ILD (Inter-Level Dielectric) layers on the first semiconductor device, wherein N is an integer greater than one; and (d) an electrically conductive line electrically coupled to the first semiconductor device. The electrically conductive line is adapted to carry a lateral electric current in a lateral direction parallel to an interfacing surface between two consecutive ILD layers of the N ILD layers. The electrically conductive line is present in at least two ILD layers of the N ILD layers. The electrically conductive line does not comprise an electrically conductive via that is adapted to carry a vertical electric current in a vertical direction perpendicular to the interfacing surface. | 04-23-2009 |
20090140395 | EDGE SEAL FOR THRU-SILICON-VIA TECHNOLOGY - One or more multilayer back side metallurgy (BSM) stack structures are formed on thru-silicon-vias (TSV). The multiple layers of metal may include an adhesion layer of chromium on the semiconductor wafer back side, a conductive layer of copper, diffusion barrier layer of nickel and a layer of nobel metal, such as, gold. To prevent edge attack of copper after dicing, the layer of nickel is formed to seal the copper edge. To also prevent edge attack of the layer of nickel after dicing, the layer of gold is formed to seal both the layer of copper and the layer of nickel. | 06-04-2009 |
20090152724 | IC INTERCONNECT FOR HIGH CURRENT - IC interconnect for high current device, design structure thereof and method are disclosed. One embodiment of the IC interconnect includes a first via positioned in a dielectric and coupled to a high current device at one end; a buffer metal segment positioned in a dielectric and coupled to the first via at the other end thereof; and a plurality of second vias positioned in a dielectric and coupled to the buffer metal segment at one end and to a metal power line at the other end thereof, wherein the buffer metal segment is substantially shorter in length than the metal power line. | 06-18-2009 |
20090253239 | METHOD AND STRUCTURE FOR BALLAST RESISTOR - A method for fabricating a low-value resistor such as a ballast resistor for bipolar junction transistors. The resistor may be fabricated using layers of appropriate sheet resistance so as to achieve low resistance values in a compact layout. The method may rely on layers already provided by a conventional CMOS process flow, such as contact plugs and fully silicided (FUSI) metal gates. | 10-08-2009 |
20090273084 | OPTICALLY TRANSPARENT WIRES FOR SECURE CIRCUITS AND METHODS OF MAKING SAME - A structure and a method. The method includes: forming a dielectric layer on a substrate; forming electrically conductive first and second wires in the dielectric layer, top surfaces of the first and second wires coplanar with a top surface of the dielectric layer; and either (i) forming an electrically conductive third wire on the top surface of the dielectric layer, and over the top surfaces of the first and second wires, the third wire electrically contacting each of the first and second wires, the third wire not detectable by optical microscopy or (ii) forming an electrically conductive third wire between the top surface of the dielectric layer and the substrate, the third wire electrically contacting each of the first and second wires, the third wire not detectable by optical microscopy. | 11-05-2009 |
20100032809 | METAL WIRING STRUCTURE FOR INTEGRATION WITH THROUGH SUBSTRATE VIAS - An array of through substrate vias (TSVs) is formed through a semiconductor substrate and a contact-via-level dielectric layer thereupon. A metal-wire-level dielectric layer and a line-level metal wiring structure embedded therein are formed directly on the contact-via-level dielectric layer. The line-level metal wiring structure includes cheesing holes that are filled with isolated portions of the metal-wire-level dielectric layer. In one embodiment, the entirety of the cheesing holes is located outside the area of the array of the TSVs to maximize the contact area between the TSVs and the line-level metal wiring structure. In another embodiment, a set of cheesing holes overlying an entirety of seams in the array of TSVs is formed to prevent trapping of any plating solution in the seams of the TSVs during plating to prevent corrosion of the TSVs at the seams. | 02-11-2010 |
20100210043 | IN-LINE DEPTH MEASUREMENT OF THRU SILICON VIA - A system, method and device for measuring a depth of a Through-Silicon-Via (TSV) in a semiconductor device region on a wafer during in-line semiconductor fabrication, includes a resistance measurement trench structure having length and width dimensions in a substrate, ohmic contacts on a surface of the substrate disposed on opposite sides of the resistance measurement trench structure, and an unfilled TSV structure in semiconductor device region having an unknown depth. A testing circuit makes contact with the ohmic contacts and measures a resistance therebetween, and a processor connected to the testing circuit calculates a depth of the trench structure and the unfilled TSV structure based on the resistance measurement. The resistance measurement trench structure and the unfilled TSV are created simultaneously during fabrication. | 08-19-2010 |
20110185330 | METAL WIRING STRUCTURE FOR INTEGRATION WITH THROUGH SUBSTRATE VIAS - An array of through substrate vias (TSVs) is formed through a semiconductor substrate and a contact-via-level dielectric layer thereupon. A metal-wire-level dielectric layer and a line-level metal wiring structure embedded therein are formed directly on the contact-via-level dielectric layer. The line-level metal wiring structure includes cheesing holes that are filled with isolated portions of the metal-wire-level dielectric layer. In one embodiment, the entirety of the cheesing holes is located outside the area of the array of the TSVs to maximize the contact area between the TSVs and the line-level metal wiring structure. In another embodiment, a set of cheesing holes overlying an entirety of seams in the array of TSVs is formed to prevent trapping of any plating solution in the seams of the TSVs during plating to prevent corrosion of the TSVs at the seams. | 07-28-2011 |
20110284280 | OPTICALLY TRANSPARENT WIRES FOR SECURE CIRCUITS AND METHODS OF MAKING SAME - A structure and a method. The method includes: forming a dielectric layer on a substrate; forming electrically conductive first and second wires in the dielectric layer, top surfaces of the first and second wires coplanar with a top surface of the dielectric layer; and either (i) forming an electrically conductive third wire on the top surface of the dielectric layer, and over the top surfaces of the first and second wires, the third wire electrically contacting each of the first and second wires, the third wire not detectable by optical microscopy or (ii) forming an electrically conductive third wire between the top surface of the dielectric layer and the substrate, the third wire electrically contacting each of the first and second wires, the third wire not detectable by optical microscopy. | 11-24-2011 |
20120058611 | METHODS OF FORMING AND PROGRAMMING AN ELECTRONICALLY PROGRAMMABLE RESISTOR - Methods of electrically programming a diffusion resistor by using trapped charge in a trapped charge region adjacent to the resistor to vary the resistance of the resistor, and the resistor, are disclosed. In one embodiment, a method includes forming a diffusion resistor in a substrate; forming a trapped charge region adjacent to the diffusion resistor; and adjusting a resistance of the diffusion resistor by controlling the trapped charge in the trapped charge region. | 03-08-2012 |
20120126370 | THIN FILM RESISTORS AND METHODS OF MANUFACTURE - A method of forming a semiconductor structure includes: forming a resistor over a substrate; forming at least one first contact in contact with the resistor; and forming at least one second contact in contact with the resistor. The resistor is structured and arranged such that current flows from the at least one first contact to the at least one second contact through a central portion of the resistor. The resistor includes at least one extension extending laterally outward from the central portion in a direction parallel to the current flow. The method includes sizing the at least one extension based on a thermal diffusion length of the resistor. | 05-24-2012 |
20120146186 | THERMALLY CONTROLLED REFRACTORY METAL RESISTOR - A structure and method of fabricating the structure includes a semiconductor substrate having a top surface defining a horizontal direction and a plurality of interconnect levels stacked from a lowermost level proximate the top surface of the semiconductor substrate to an uppermost level furthest from the top surface. Each of the interconnect levels include vertical metal conductors physically connected to one another in a vertical direction perpendicular to the horizontal direction. The vertical conductors in the lowermost level being physically connected to the top surface of the substrate, and the vertical conductors forming a heat sink connected to the semiconductor substrate. A resistor is included in a layer immediately above the uppermost level. The vertical conductors being aligned under a downward vertical resistor footprint of the resistor, and each interconnect level further include horizontal metal conductors positioned in the horizontal direction and being connected to the vertical conductors. | 06-14-2012 |
20140038381 | THERMALLY CONTROLLED REFRACTORY METAL RESISTOR - A structure and method of fabricating the structure includes a semiconductor substrate having a top surface defining a horizontal direction and a plurality of interconnect levels stacked from a lowermost level proximate the top surface of the semiconductor substrate to an uppermost level furthest from the top surface. Each of the interconnect levels include vertical metal conductors physically connected to one another in a vertical direction perpendicular to the horizontal direction. The vertical conductors in the lowermost level being physically connected to the top surface of the substrate, and the vertical conductors forming a heat sink connected to the semiconductor substrate. A resistor is included in a layer immediately above the uppermost level. The vertical conductors being aligned under a downward vertical resistor footprint of the resistor, and each interconnect level further include horizontal metal conductors positioned in the horizontal direction and being connected to the vertical conductors. | 02-06-2014 |
20140332973 | INLINE MEASUREMENT OF THROUGH-SILICON VIA DEPTH - A through-silicon via (TSV) capacitive test structure and method of determining TSV depth based on capacitance is disclosed. The TSV capacitive test structure is formed from a plurality of TSV bars that are evenly spaced. A first group of bars are electrically connected to form a first capacitor node, and a second group of bars is electrically connected to form a second capacitor node. The capacitance is measured, and a TSV depth is computed, prior to backside thinning. The computed TSV depth may then be fed to downstream grinding and/or polishing tools to control the backside thinning process such that the semiconductor wafer is thinned such that the backside is flush with the TSV. | 11-13-2014 |
20140368292 | MICRO-ELECTRO-MECHANICAL SYSTEM (MEMS) STRUCTURE AND DESIGN STRUCTURES - Micro-Electro-Mechanical System (MEMS) structures, methods of manufacture and usage, and design structures are disclosed herein. The method includes applying a first voltage polarity to an actuator of a Micro-Electro-Mechanical System (MEMS) structure to place the MEMS structure in a predetermined state for a first operating condition. The method further includes applying a second voltage polarity which is opposite from the first voltage polarity to the actuator of the MEMS structure during a subsequent operating condition. | 12-18-2014 |