Patent application number | Description | Published |
20080254630 | DEVICE AND METHODOLOGY FOR REDUCING EFFECTIVE DIELECTRIC CONSTANT IN SEMICONDUCTOR DEVICES - Method of manufacturing a semiconductor device structure, including the steps of providing a structure having an insulator layer with at least one interconnect, forming a sub lithographic template mask over the insulator layer, and selectively etching the insulator layer through the sub lithographic template mask to form sub lithographic features spanning to a sidewall of the at least one interconnect. | 10-16-2008 |
20080265409 | INTEGRATED CIRCUIT HARD MASK PROCESSING SYSTEM - An integrated circuit hard mask processing system is provided including providing a substrate having an integrated circuit; forming an interconnect layer over the integrated circuit; applying a low-K dielectric layer over the interconnect layer; applying a hard mask layer over the low-K dielectric layer; forming a via opening through the hard mask layer and the low-K dielectric layer to the interconnect layer; applying a first fluid and a second fluid in the via opening for removing an overhang of the hard mask layer; depositing an interconnect metal in the via opening; and chemical-mechanical polishing the interconnect metal and the ultra low-K dielectric layer. | 10-30-2008 |
20090008361 | OXIDANT AND PASSIVANT COMPOSITION AND METHOD FOR USE IN TREATING A MICROELECTRONIC STRUCTURE - A composition that may be used for cleaning a metal containing conductor layer, such as a copper containing conductor layer, within a microelectronic structure includes an aqueous acid, along with an oxidant material and a passivant material contained within the aqueous acid. The composition does not include an abrasive material. The composition is particularly useful for cleaning a residue from a copper containing conductor layer and an adjoining dielectric layer that provides an aperture for accessing the copper containing conductor layer within a microelectronic structure. | 01-08-2009 |
20090108442 | SELF-ASSEMBLED STRESS RELIEF INTERFACE - A method of forming an interconnect assembly is provided in which contacts exposed at a face of a first element such as, for example, a microelectronic element are aligned and joined with corresponding contacts of an interconnect element confronting the face of the first element. At least one of the i) the contacts of the first element, ii) the corresponding contacts of the interconnect element, iii) a joining metal between the contacts and the corresponding contacts includes a catalyst metal. Subsequently, a material including an organic component contacting the catalyst metal reacts to form volume expansion accommodation elements in the presence of the catalyst metal, the reaction being limited by proximity with the catalyst metal, such that the interconnect assembly includes volume expansion accommodation elements adjacent to the joined contacts. | 04-30-2009 |
20090140432 | PAD STRUCTURE TO PROVIDE IMPROVED STRESS RELIEF - A semiconductor interconnection comprises a semiconductor device, a substrate adjacent the semiconductor device, and a plurality of spring contacts on the semiconductor device or the substrate. A plurality of solder connections are on the opposite semiconductor device or substrate. Each spring contact comprises a contact surface and a conductive material on the contact surface. Upon assembly of the semiconductor device and the substrate, the conductive material on the plurality of spring contacts makes contact with each of the plurality of solder connections. The conductive material is in a liquid state at manufacturing or operating temperatures of the semiconductor device. Thus, the conductive material could be a solid at room temperature and transition to a liquid state at the semiconductor's manufacturing or operating temperatures. | 06-04-2009 |
20100013104 | INTEGRATED CIRCUIT HARD MASK PROCESSING SYSTEM - An integrated circuit processing system is provided including a substrate having an integrated circuit; an interconnect layer over the integrated circuit; a low-K dielectric layer over the interconnect layer; a hard mask layer over the low-K dielectric layer; a via opening through the hard mask layer and the low-K dielectric layer to the interconnect layer; and an interconnect metal in the via opening. | 01-21-2010 |
20100301475 | Forming Semiconductor Chip Connections - Systems and methods are disclosed that enable forming semiconductor chip connections. In one embodiment, the semiconductor chip includes a body having a polyhedron shape with a pair of opposing sides; and a solder member extending along a side that extends between the pair of opposing sides of the polyhedron shape. | 12-02-2010 |
20110111590 | DEVICE AND METHODOLOGY FOR REDUCING EFFECTIVE DIELECTRIC CONSTANT IN SEMICONDUCTOR DEVICES - Method of manufacturing a structure which includes the steps of providing a structure having an insulator layer with at least one interconnect, forming a sub lithographic template mask over the insulator layer, and selectively etching the insulator layer through the sub lithographic template mask to form sub lithographic features spanning to a sidewall of the plurality of interconnects. | 05-12-2011 |
20110180920 | CO-AXIAL RESTRAINT FOR CONNECTORS WITHIN FLIP-CHIP PACKAGES - An assembly can include a microelectronic element such as, for example, a semiconductor element having circuits and semiconductor devices fabricated therein, and a plurality of electrical connectors, e.g., solder balls attached to contacts of the microelectronic element. The connectors can be surrounded by first, inner regions | 07-28-2011 |
20110227225 | COPPER ALLOY VIA BOTTOM LINER - Improved mechanical and adhesive strength and resistance to breakage of copper integrated circuit interconnections is obtained by forming a copper alloy in a copper via/wiring connection in an integrated circuit while minimizing adverse electrical effects of the alloy by confining the alloy to an interfacial region of said via/wiring connection and not elsewhere by a barrier which reduces or substantially eliminates the thickness of alloy in the conduction path. The alloy location and composition are further stabilized by reaction of all available alloying material with copper, copper alloys or other metals and their alloys. | 09-22-2011 |
20120187546 | BILAYER TRENCH FIRST HARDMASK STRUCTURE AND PROCESS FOR REDUCED DEFECTIVITY - A method and structure for transferring a lithographic pattern into a substrate includes forming a dielectric hardmask layer over a dielectric substrate. A metal hardmask layer is formed over the dielectric hardmask layer. A protective capping hardmask layer or capping film is formed over the metal hardmask layer, and a lithographic structure for pattern transfer is formed over the capping layer. A pattern is transferred into the dielectric substrate using the defined lithographic structure. The capping hardmask layer can be removed during subsequent processing. | 07-26-2012 |
20120187561 | FORMING SEMICONDUCTOR CHIP CONNECTIONS - Systems and methods are disclosed that enable forming semiconductor chip connections. In one embodiment, the semiconductor chip includes a body having a polyhedron shape with a pair of opposing sides; and a solder member extending along a side that extends between the pair of opposing sides of the polyhedron shape. | 07-26-2012 |
20120223434 | CO-AXIAL RESTRAINT FOR CONNECTORS WITHIN FLIP-CHIP PACKAGES - An assembly can include a microelectronic element such as, for example, a semiconductor element having circuits and semiconductor devices fabricated therein, and a plurality of electrical connectors, e.g., solder balls attached to contacts of the microelectronic element. The connectors can be surrounded by first, inner regions | 09-06-2012 |
20120292763 | ELECTROMIGRATION IMMUNE THROUGH-SUBSTRATE VIAS - A through-substrate via (TSV) structure includes at least two electrically conductive via segments embedded in a substrate and separated from each other by an electrically conductive barrier layer therebetween. The length of each individual conductive via segment is typically equal to, or less than, the Blech length of the conductive material so that the stress-induced back flow force, generated by each conductive barrier layer, cancels the electromigration force in each conductive via segment. Consequently, the TSV structures are immune to electromigration, and provide reliable electrical connections among a chips stacked in 3 dimensions. | 11-22-2012 |
20130041894 | Mitigating Environment, Health, and Safety Complications - A method of identifying a substitute chemical includes receiving, at a computer, a trial set of properties that describes a function in a desired chemical process of a chemical for substitution, performing a distributed search using objective similarity criteria based on the trial set of properties to identify a first set of candidate chemicals, prioritizing the first set of candidate chemicals into a second set of candidate chemicals, determining Environmental, Health, and Safety (EHS) data parameter values for each chemical of the second set of candidate chemicals, normalizing disparate EHS data parameter values into associated EHS properties, prioritizing the second set of candidate chemicals into a third set of candidate chemicals, and prioritizing the third set of candidate chemicals into a fourth set of candidate chemicals according to the risk posed by the desired chemical process. | 02-14-2013 |
20130123159 | AQUEOUS CERIUM-CONTAINING SOLUTION HAVING AN EXTENDED BATH LIFETIME FOR REMOVING MASK MATERIAL - An aqueous solution of a cerium (IV) complex or salt having an extended lifetime is provided. In one embodiment, the extended lifetime is achieved by adding at least one booster additive to an aqueous solution of the cerium (IV) complex or salt. In another embodiment, the extended lifetime is achieved by providing an aqueous solution of a cerium (IV) complex or salt and a cerium (III) complex or salt. The cerium (III) complex or salt can be added or it can be generated in-situ by introducing a reducing agent into the aqueous solution of the cerium (IV) complex or salt. The aqueous solution can be used to remove a mask material, especially an ion implanted and patterned photoresist, from a surface of a semiconductor substrate. | 05-16-2013 |
20130145615 | Detecting Leaks In A Fluid Cooling System By Sensing For A Drop Of Fluid Pressure In The System - Embodiments of the present invention relate to detecting leaks in a fluid cooling system. One aspect of the present invention concerns an apparatus for detecting leaks in a fluid cooling system that includes a pressure exerting device for applying a pressure on a supply hose and a return hose of the cooling system, and a pressure gauge coupled to the pressure exerting device for detecting a drop of fluid pressure in the cooling system while the pressure is applied. The drop of fluid pressure indicates that there may be a leak in the cooling system. | 06-13-2013 |
20130171829 | Titanium-Nitride Removal - A chemical solution that removes undesired metal hard mask yet remains selective to the device wiring metallurgy and dielectric materials. The present invention decreases aspect ratio by selective removal of the metal hard mask before the metallization of the receiving structures without adverse damage to any existing metal or dielectric materials required to define the semiconductor device, e.g. copper metallurgy or device dielectric. Thus, an improved aspect ratio for metal fill without introducing any excessive trapezoidal cross-sectional character to the defined metal receiving structures of the device will result. | 07-04-2013 |
20130200040 | TITANIUM NITRIDE REMOVAL - A chemical solution that removes undesired metal hard mask yet remains selective to the device wiring metallurgy and dielectric materials. The present disclosure decreases aspect ratio by selective removal of the metal hard mask before the metallization of the receiving structures without adverse damage to any existing metal or dielectric materials required to define the semiconductor device, e.g. copper metallurgy or device dielectric. Thus, an improved aspect ratio for metal fill without introducing any excessive trapezoidal cross-sectional character to the defined metal receiving structures of the device will result. | 08-08-2013 |
20130203231 | SELECTIVE ETCH CHEMISTRY FOR GATE ELECTRODE MATERIALS - A chemical solution including an aqueous solution, an oxidizing agent, and a pH stabilizer selected from quaternary ammonium salts and quaternary ammonium alkali can be employed to remove metallic materials in cavities for forming a semiconductor device. For example, metallic materials in gate cavities for forming a replacement gate structure can be removed by the chemical solution of the present disclosure with, or without, selectivity among multiple metallic materials such as work function materials. The chemical solution of the present disclosure provides different selectivity among metallic materials than known etchants in the art. | 08-08-2013 |
20130334691 | SIDEWALLS OF ELECTROPLATED COPPER INTERCONNECTS - A structure formed in an opening having a substantially vertical sidewall defined by a non-metallic material and having a substantially horizontal bottom defined by a conductive pad, the structure including a diffusion barrier covering the sidewall and a fill composed of conductive material. The structure including a first intermetallic compound separating the diffusion barrier from the conductive material, the first intermetallic compound comprises an alloying material and the conductive material, and is mechanically bound to the conductive material, the alloying material is at least one of the materials selected from the group of chromium, tin, nickel, magnesium, cobalt, aluminum, manganese, titanium, zirconium, indium, palladium, and silver; and a first high friction interface located between the diffusion barrier and the first intermetallic compound and parallel to the sidewall of the opening, wherein the first high friction interface results in a mechanical bond between the diffusion barrier and the first intermetallic compound. | 12-19-2013 |
20140027296 | SIDEWALLS OF ELECTROPLATED COPPER INTERCONNECTS - A structure formed in an opening having a substantially vertical sidewall defined by a non-metallic material and having a substantially horizontal bottom defined by a conductive pad, the structure including a diffusion barrier covering the sidewall and a fill composed of conductive material. The structure including a first intermetallic compound separating the diffusion barrier from the conductive material, the first intermetallic compound comprises an alloying material and the conductive material, and is mechanically bound to the conductive material, the alloying material is at least one of the materials selected from the group of chromium, tin, nickel, magnesium, cobalt, aluminum, manganese, titanium, zirconium, indium, palladium, and silver; and a first high friction interface located between the diffusion barrier and the first intermetallic compound and parallel to the sidewall of the opening, wherein the first high friction interface results in a mechanical bond between the diffusion barrier and the first intermetallic compound. | 01-30-2014 |
20140027911 | SIDEWALLS OF ELECTROPLATED COPPER INTERCONNECTS - A structure formed in an opening having a substantially vertical sidewall defined by a non-metallic material and having a substantially horizontal bottom defined by a conductive pad, the structure including a diffusion barrier covering the sidewall and a fill composed of conductive material. The structure including a first intermetallic compound separating the diffusion barrier from the conductive material, the first intermetallic compound comprises an alloying material and the conductive material, and is mechanically bound to the conductive material, the alloying material is at least one of the materials selected from the group of chromium, tin, nickel, magnesium, cobalt, aluminum, manganese, titanium, zirconium, indium, palladium, and silver; and a first high friction interface located between the diffusion barrier and the first intermetallic compound and parallel to the sidewall of the opening, wherein the first high friction interface results in a mechanical bond between the diffusion barrier and the first intermetallic compound. | 01-30-2014 |
20140027912 | SIDEWALLS OF ELECTROPLATED COPPER INTERCONNECTS - A structure formed in an opening having a substantially vertical sidewall defined by a non-metallic material and having a substantially horizontal bottom defined by a conductive pad, the structure including a diffusion barrier covering the sidewall and a fill composed of conductive material. The structure including a first intermetallic compound separating the diffusion barrier from the conductive material, the first intermetallic compound comprises an alloying material and the conductive material, and is mechanically bound to the conductive material, the alloying material is at least one of the materials selected from the group of chromium, tin, nickel, magnesium, cobalt, aluminum, manganese, titanium, zirconium, indium, palladium, and silver; and a first high friction interface located between the diffusion barrier and the first intermetallic compound and parallel to the sidewall of the opening, wherein the first high friction interface results in a mechanical bond between the diffusion barrier and the first intermetallic compound. | 01-30-2014 |
20140128307 | CLEANING COMPOSITION AND PROCESS FOR CLEANING SEMICONDUCTOR DEVICES AND/OR TOOLING DURING MANUFACTURING THEREOF - Cleaning solutions and processes for cleaning semiconductor devices or semiconductor tooling during manufacture thereof generally include contacting the semiconductor devices or semiconductor tooling with an acidic aqueous cleaning solution free of a fluorine containing compound, the acidic aqueous cleaning solution including at least one antioxidant and at least one non-oxidizing acid. | 05-08-2014 |
20140191418 | METAL TO METAL BONDING FOR STACKED (3D) INTEGRATED CIRCUITS - The present invention provides a stabilized fine textured metal microstructure that constitutes a durable activated surface usable for bonding a 3D stacked chip. A fine-grain layer that resists self anneal enables metal to metal bonding at moderate time and temperature and wider process flexibility. | 07-10-2014 |
20140210040 | ELECTRONIC FUSE LINE WITH MODIFIED CAP - An electronic fuse structure having an M | 07-31-2014 |
20140312265 | Titanium-Nitride Removal - A chemical solution that removes undesired metal hard mask yet remains selective to the device wiring metallurgy and dielectric materials. The present invention decreases aspect ratio by selective removal of the metal hard mask before the metallization of the receiving structures without adverse damage to any existing metal or dielectric materials required to define the semiconductor device, e.g. copper metallurgy or device dielectric. Thus, an improved aspect ratio for metal fill without introducing any excessive trapezoidal cross-sectional character to the defined metal receiving structures of the device will result. | 10-23-2014 |
20140332929 | FORMING SEMICONDUCTOR CHIP CONNECTIONS - Various embodiments include semiconductor structures. In one embodiment, the semiconductor structure includes a chip having a body having a polyhedron shape with a pair of opposing sides; and a solder member extending along a side that extends between the pair of opposing sides of the polyhedron shape. | 11-13-2014 |
20140374903 | METAL TO METAL BONDING FOR STACKED (3D) INTEGRATED CIRCUITS - The present invention provides a stabilized fine textured metal microstructure that constitutes a durable activated surface usable for bonding a 3D stacked chip. A fine-grain layer that resists self anneal enables metal to metal bonding at moderate time and temperature and wider process flexibility. | 12-25-2014 |
20150021736 | ELECTRONIC FUSE LINE WITH MODIFIED CAP - An electronic fuse structure having an M | 01-22-2015 |
20150024989 | CLEANING COMPOSITION AND PROCESS FOR CLEANING SEMICONDUCTOR DEVICES AND/OR TOOLING DURING MANUFACTURING THEREOF - Cleaning solutions and processes for cleaning semiconductor devices or semiconductor tooling during manufacture thereof generally include contacting the semiconductor devices or semiconductor tooling with an acidic aqueous cleaning solution free of a fluorine containing compound, the acidic aqueous cleaning solution including at least one antioxidant and at least one non-oxidizing acid. | 01-22-2015 |
20150056804 | BOTTOM-UP PLATING OF THROUGH-SUBSTRATE VIAS - According to one embodiment of the present invention, a method of plating a TSV hole in a substrate is provided. The TSV hole may include an open end terminating at a conductive pad, a stack of wiring levels, and a plurality of chip interconnects. The method of plating a TSV may include attaching a handler to the plurality of chip interconnects, the handler having a conductive layer in electrical contact with the plurality of chip interconnects; exposing a closed end of the TSV hole, including the conductive pad, to an electrolyte solution; and applying an electrical potential along an electrical path from the conductive layer to the conductive pad causing conductive material from the electrolyte solution to deposit on the conductive pad and within the TSV hole, the electrical path including the conductive layer, the plurality of chip interconnects, the stack of wiring levels and the conductive pad. | 02-26-2015 |
20150069421 | WAFER TO WAFER ALIGNMENT BY LED/LSD DEVICES - A method for wafer alignment includes forming a first alignment circuit within a first semiconductor wafer; the first alignment circuit is configured to emit an optical signal. Next, the first alignment circuit is activated upon receiving a first activation signal from a wafer bonding tool then the optical signal is sent to a second alignment circuit in a second semiconductor wafer in overlapping relation to the first semiconductor wafer. The second alignment circuit transmits a second activation signal to the wafer bonding tool and consequently the wafer bonding tool initiates an alignment technique between the first and second semiconductor wafers. The alignment technique uses the first and second alignment circuits for optical alignment. | 03-12-2015 |