Patent application number | Description | Published |
20080231312 | Structure for modeling stress-induced degradation of conductive interconnects - A structure representative of a conductive interconnect of a microelectronic element is provided, which may include a conductive metallic plate having an upper surface, a lower surface, and a plurality of peripheral edges extending between the upper and lower surfaces, the upper surface defining a horizontally extending plane. The structure may also include a lower via having a top end in conductive communication with the metallic plate and a bottom end vertically displaced from the top end. A lower conductive or semiconductive element can be in contact with the bottom end of the lower via. An upper metallic via can lie in at least substantial vertical alignment with the lower conductive via, the upper metallic via having a bottom end in conductive communication with the metallic plate and a top end vertically displaced from the bottom end. The upper metallic via may have a width at least about ten times than the length of the metallic plate and about ten times smaller than the width of the metallic plate. The structure may further include an upper metallic line element in contact with the top end of the upper metallic via. | 09-25-2008 |
20090014884 | SLOTS TO REDUCE ELECTROMIGRATION FAILURE IN BACK END OF LINE STRUCTURE - A back-end of the line (BEOL) structure and method are disclosed. In one embodiment the BEOL structure may include: a copper line in an ultra low-k dielectric, the copper line connected on one end to a cathode via and on another end to an anode via; and a plurality of slots extending laterally along a length of the copper line, the plurality of slots being non-continuous along the length of the copper line, and wherein the plurality of slots reduce electromigration failure in the BEOL structure by enabling copper extrusions to occur along the plurality of slots. | 01-15-2009 |
20090302476 | Structures and Methods to Enhance CU Interconnect Electromigration (EM) Performance - The invention generally relates to semiconductor devices, and more particularly to structures and methods for enhancing electromigration (EM) performance in interconnects. A method includes forming an interconnect, forming a cap on the interconnect, and forming a plurality of holes in the cap to improve electromigration performance of the interconnect. | 12-10-2009 |
20100164116 | ELECTROMIGRATION RESISTANT VIA-TO-LINE INTERCONNECT - A liner-to-liner direct contact is formed between an upper metallic liner of a conductive via and a lower metallic liner of a metal line below. The liner-to-liner contact impedes abrupt electromigration failures and enhances electromigration resistance of the metal interconnect structure. The at least one dielectric material portion may include a plurality of dielectric material portions arranged to insure direct contact of between the upper metallic liner and the lower metallic liner. Alternatively, the at least one dielectric material portion may comprise a single dielectric portion of which the area has a sufficient lateral overlap with the area of the conductive via to insure that a liner-to-liner direct contact is formed within the range of allowed lithographic overlay variations. | 07-01-2010 |
20100176514 | INTERCONNECT WITH RECESSED DIELECTRIC ADJACENT A NOBLE METAL CAP - The invention comprises a copper interconnect structure that includes a noble metal cap with dielectric immediately adjacent the copper/noble metal cap interface recessed from the noble metal cap. | 07-15-2010 |
20110115508 | DETERMINING CRITICAL CURRENT DENSITY FOR INTERCONNECT - Solutions for determining a critical current density of a line are disclosed. In one embodiment a method of determining a critical current density in a line includes: applying a temperature condition to each of a plurality of samples including the line; calculating a cross-sectional area of the line for each of the plurality samples using data about an electrical resistance of the line over each of the temperature conditions; measuring an electrical current reading through the line for each of the plurality of samples; determining a current density through the line for each of the plurality of samples by dividing each electrical current reading by each corresponding cross-sectional area; determining an electromigration (EM) failure time for each of the plurality of samples; and determining the critical current density of the line using the current density and the plurality of EM failure times. | 05-19-2011 |
20110283249 | METHOD AND SYSTEM TO PREDICT A NUMBER OF ELECTROMIGRATION CRITICAL ELEMENTS - A method and system to predict a number of electromigration critical elements in semiconductor products. This method includes determining critical element factors for a plurality of library elements in a circuit design library using a design tool running on a computer device and based on at least one of an increased reliability temperature and an increased expected current. The method also includes determining a number of critical elements in a product based on: (i) numbers of respective ones of the plurality of library elements comprised in the product, and (ii) the critical element factors. | 11-17-2011 |
20120080771 | 3D VIA CAPACITOR WITH A FLOATING CONDUCTIVE PLATE FOR IMPROVED RELIABILITY - The present invention provides a 3D via capacitor and a method for forming the same. The capacitor includes an insulating layer on a substrate. The insulating layer has a via having sidewalls and a bottom. A first electrode overlies the sidewalls and at least a portion of the bottom of the via. A first high-k dielectric material layer overlies the first electrode. A first conductive plate is over the first high-k dielectric material layer. A second high-k dielectric material layer overlies the first conductive plate and leaves a remaining portion of the via unfilled. A second electrode is formed in the remaining portion of the via. The first conductive plate is substantially parallel to the first electrode and is not in contact with the first and second electrodes. An array of such 3D via capacitors is also provided. | 04-05-2012 |
20120119366 | ELECTROMIGRATION RESISTANT VIA-TO-LINE INTERCONNECT - A liner-to-liner direct contact is formed between an upper metallic liner of a conductive via and a lower metallic liner of a metal line below. The liner-to-liner contact impedes abrupt electromigration failures and enhances electromigration resistance of the metal interconnect structure. The at least one dielectric material portion may include a plurality of dielectric material portions arranged to insure direct contact of between the upper metallic liner and the lower metallic liner. Alternatively, the at least one dielectric material portion may comprise a single dielectric portion of which the area has a sufficient lateral overlap with the area of the conductive via to insure that a liner-to-liner direct contact is formed within the range of allowed lithographic overlay variations. | 05-17-2012 |
20120261724 | STACKABLE PROGRAMMABLE PASSIVE DEVICE AND A TESTING METHOD - A programmable passive device comprising a first node and a second node. A plurality of passive device elements electrically coupled to the first node. A plurality of switches are electrically coupled to at least the second node and selectively coupled to a number of the plurality of passive device elements to provide the programmable passive device with a pre-determined value. | 10-18-2012 |
20120261793 | ELECTRICAL FUSE AND METHOD OF MAKING THE SAME - An improved electrical-fuse (e-fuse) device including a dielectric layer having a first top surface, two conductive features embedded in the dielectric layer and a fuse element. Each conductive feature has a second top surface and a metal cap directly on the second top surface. Each metal cap has a third top surface that is above the first top surface of the dielectric layer. The fuse element is on the third top surface of each metal cap and on the first top surface of the dielectric layer. A method of forming the e-fuse device is also provided. | 10-18-2012 |
20120306048 | ELECTRICALLY PROGRAMMABLE METAL FUSE - A metal electrically programmable fuse (“eFuse”) includes a metal strip, having a strip width, of a metal line adjoined to wide metal line portions, having widths greater than the metal strip width, at both ends of the metal strip. The strip width can be a lithographic minimum dimension, and the ratio of the length of the metal strip to the strip width is greater than 5 to localize heating around the center of the metal strip during programming. Localization of heating reduces required power for programming the metal eFuse. Further, a gradual temperature gradient is formed during the programming within a portion of the metal strip that is longer than the Blech length so that electromigration of metal gradually occurs reliably at the center portion of the metal strip. Metal line portions are provides at the same level as the metal eFuse to physically block debris generated during programming. | 12-06-2012 |
20120313194 | SEMICONDUCTOR SWITCHING DEVICE AND METHOD OF MAKING THE SAME - A switching device including a first dielectric layer having a first top surface, two conductive features embedded in the first dielectric layer, each conductive feature having a second top surface that is substantially coplanar with the first top surface of the first dielectric layer, and a set of discrete islands of a low diffusion mobility metal between the two conductive features. The discrete islands of the low diffusion mobility metal may be either on the first top surface or embedded in the first dielectric layer. The electric conductivity across the two conductive features of the switching device increases when a prescribed voltage is applied to the two conductive features. A method of forming such a switching device is also provided. | 12-13-2012 |
20130071998 | Electrical Fuse With Metal Line Migration - An electrical fuse device is disclosed. A circuit apparatus can include the fuse device, a first circuit element and a second circuit element. The fuse includes a first contact that has a first electromigration resistance, a second contact that has a second electromigration resistance and a metal line, which is coupled to the first contact and to the second contact, that has a third electromigration resistance that is lower than the second electromigration resistance. The first circuit element is coupled to the first contact and the second circuit element coupled to the second contact. The fuse is configured to conduct a programming current from the first contact to the second contact through the metal line. Further, the programming current causes the metal line to electromigrate away from the second contact to electrically isolate the second circuit element from the first circuit element. | 03-21-2013 |
20130093089 | Interconnect Structure With An Electromigration and Stress Migration Enhancement Liner - An electromigration and stress migration enhancement liner is provided for use in an interconnect structure. The liner includes a metal that has a thickness at a bottom of the at least one via opening and on an exposed portion of an underlying conductive feature that is greater than a remaining thickness that is located on exposed sidewalls of the interconnect dielectric material. The thinner portion of the electromigration and stress migration enhancement liner is located between the interconnect dielectric material and an overlying diffusion barrier. The thicker portion of the electromigration and stress migration enhancement liner is located between the underlying conductive feature and the diffusion barrier as well as between an adjacent dielectric capping layer and the diffusion barrier. The remainder of the at least one via opening is filled with an adhesion layer and a conductive material. | 04-18-2013 |
20130161791 | 3D VIA CAPACITOR WITH A FLOATING CONDUCTIVE PLATE FOR IMPROVED RELIABILITY - The present invention provides a 3D via capacitor and a method for forming the same. The capacitor includes an insulating layer on a substrate. The insulating layer has a via having sidewalls and a bottom. A first electrode overlies the sidewalls and at least a portion of the bottom of the via. A first high-k dielectric material layer overlies the first electrode. A first conductive plate is over the first high-k dielectric material layer. A second high-k dielectric material layer overlies the first conductive plate and leaves a remaining portion of the via unfilled. A second electrode is formed in the remaining portion of the via. The first conductive plate is substantially parallel to the first electrode and is not in contact with the first and second electrodes. An array of such 3D via capacitors is also provided. | 06-27-2013 |
20130164905 | 3D VIA CAPACITOR WITH A FLOATING CONDUCTIVE PLATE FOR IMPROVED RELIABILITY - The present invention provides a 3D via capacitor and a method for forming the same. The capacitor includes an insulating layer on a substrate. The insulating layer has a via having sidewalls and a bottom. A first electrode overlies the sidewalls and at least a portion of the bottom of the via. A first high-k dielectric material layer overlies the first electrode. A first conductive plate is over the first high-k dielectric material layer. A second high-k dielectric material layer overlies the first conductive plate and leaves a remaining portion of the via unfilled. A second electrode is formed in the remaining portion of the via. The first conductive plate is substantially parallel to the first electrode and is not in contact with the first and second electrodes. An array of such 3D via capacitors is also provided. | 06-27-2013 |
20130185684 | INTEGRATED CIRCUIT DESIGN METHOD AND SYSTEM - Disclosed is an integrated circuit design method that determines maximum direct currents for metal components and uses them as design constraints in the design flow in order to avoid/minimize electromigration failures. Short and long metal components are treated differently for purposes of establishing the design constraints. For a short metal component, the maximum direct current as a function of a given temperature for a given expected lifetime of the integrated circuit is determined, another maximum direct current is determined based on the Blech length, and the higher of these two is selected and used as the design constraint for that short metal component. For a long metal component, only the maximum direct current as a function of the given temperature for the given expected lifetime is determined and used as the design constraint. Also disclosed herein are associated system and program storage device embodiments for designing an integrated circuit. | 07-18-2013 |
20130328167 | SELF-ALIGNED METAL-INSULATOR-METAL (MIM) CAPACITOR - A metal-insulator-metal (MIM) capacitor structure integrated within a back-end-of-the-line (BEOL) structure is provided. The MIM capacitor structure includes a lower electrode, i.e., a first conductive material, embedded within a dielectric material of the BEOL structure, a dielectric material liner having a dielectric constant of equal to, or greater than, silicon dioxide located atop the lower electrode, and an upper electrode, i.e., a second conductive material, positioned between vertical portions of the dielectric material liner and atop a horizontal connecting portion of the dielectric material liner. In accordance with the present disclosure, the vertical portions of the dielectric material liner do not extend onto an upper surface of the dielectric material that includes the lower electrode. | 12-12-2013 |
20140048927 | METHOD TO IMPROVE FINE CU LINE RELIABILITY IN AN INTEGRATED CIRCUIT DEVICE - Structure and methods for forming a semiconductor structure. The semiconductor structure includes a plurality of layers comprising at least one copper interconnect layer. The copper interconnect layer provides an electrical conduit between one of physically adjacent layers in the semiconductor structure and an integrated circuit in the semiconductor structure and an electronic device. A plurality of studs is positioned within the at least one copper interconnect layer. The studs are spaced apart by a distance less than or equal to a Blech length of the at least one copper interconnect layer. The Blech length is a length below which damage due to electromigration of metal atoms within the at least one copper interconnect layer does not occur. The plurality of studs comprises copper atom diffusion barriers. | 02-20-2014 |
20140124933 | COPPER INTERCONNECT STRUCTURES AND METHODS OF MAKING SAME - A structure and method of making the structure. The structure includes a dielectric layer on a substrate; a first wire formed in a first trench in the dielectric layer, a first liner on sidewalls and a bottom of the first trench and a first copper layer filling all remaining space in the first trench; a second wire formed in a second trench in the dielectric layer, a second liner on sidewalls and a bottom of the second trench and a second copper layer filling all remaining space in the second trench; and an electromigration stop formed in a third trench in the dielectric layer, a third liner on sidewalls and a bottom of the third trench and a third copper layer filling all remaining space in the third trench, the electromigration stop between and abutting respective ends of the first and second wires. | 05-08-2014 |
20140131878 | SEMICONDUCTOR DEVICES WITH ENHANCED ELECTROMIGRATION PERFORMANCE - Semiconductor devices with enhanced electromigration performance and methods of manufacture are disclosed. The method includes forming at least one metal line in electrical contact with a device. The method further includes forming at least one staple structure in electrical contact with the at least one metal line. The at least one staple structure is formed such that electrical current passing through the at least one metal line also passes through the at least staple structure to reduce electromigration issues. | 05-15-2014 |
20140162450 | INTERCONNECT STRUCTURE WITH AN ELECTROMIGRATION AND STRESS MIGRATION ENHANCEMENT LINER - An electromigration and stress migration enhancement liner is provided for use in an interconnect structure. The liner includes a metal that has a thickness at a bottom of the at least one via opening and on an exposed portion of an underlying conductive feature that is greater than a remaining thickness that is located on exposed sidewalls of the interconnect dielectric material. The thinner portion of the electromigration and stress migration enhancement liner is located between the interconnect dielectric material and an overlying diffusion barrier. The thicker portion of the electromigration and stress migration enhancement liner is located between the underlying conductive feature and the diffusion barrier as well as between an adjacent dielectric capping layer and the diffusion barrier. The remainder of the at least one via opening is filled with an adhesion layer and a conductive material. | 06-12-2014 |
20140206190 | Silicide Formation in High-Aspect Ratio Structures - Embodiments of the present invention include methods of forming a silicide layer on a semiconductor substrate. In an exemplary embodiment, a metal layer may first be deposited above a semiconductor substrate using a chemical vapor deposition process with a metal amidinate precursor and then the semiconductor substrate may be annealed, causing the semiconductor substrate to react with the metal layer forming a metal-rich silicide layer on the semiconductor substrate. Embodiments may also include forming a low-oxygen capping layer above the metal layer prior to annealing the semiconductor substrate to protect the metal layer from oxidation. The low-oxygen capping layer may, for example, be made of titanium nitride containing less than 20 parts per million of oxygen. Embodiments may further include forming a silicide layer using the above process in a contact hole above a source/drain region of a field-effect transistor, and forming a metal contact above the silicide layer. | 07-24-2014 |
20140210041 | ELECTRONIC FUSE HAVING AN INSULATION LAYER - An electronic fuse structure including etching a dual damascene feature in a dielectric layer, the dual damascene feature including a first via opening, a second via opening, and a trench opening, forming a seed layer within the dual damascene feature, the seed layer including a conductive material, and heating the dielectric layer and the seed layer causing the seed layer to reflow and fill the first via opening, the second via opening, and partially filling the trench opening to form a fuse line, a first via, and a second via. The structure further including forming an insulating layer on top of the fuse line, and forming a fill material on top of the insulating layer and substantially filling the trench opening. | 07-31-2014 |
20140239439 | ELECTRICAL FUSES AND METHODS OF MAKING ELECTRICAL FUSES - A fuse, a method of making the fuse and a circuit containing the fuse. The fuse includes an electrically conductive and conformal liner on sidewalls and the bottom of a trench; a copper layer on the conformal liner, a first thickness of the copper layer over the bottom of the trench in a lower portion of the trench greater than a second thickness of the copper layer over the sidewalls of the trench in an abutting upper portion of the trench; and a dielectric material on the copper layer in the trench, the dielectric material filling remaining space in the upper portion of said trench. | 08-28-2014 |
20140264878 | COPPER INTERCONNECT STRUCTURES AND METHODS OF MAKING SAME - A structure and method of making the structure. The structure includes a dielectric layer on a substrate; a first wire formed in a first trench in the dielectric layer, a first liner on sidewalls and a bottom of the first trench and a first copper layer filling all remaining space in the first trench; a second wire formed in a second trench in the dielectric layer, a second liner on sidewalls and a bottom of the second trench and a second copper layer filling all remaining space in the second trench; and an electromigration stop formed in a third trench in the dielectric layer, a third liner on sidewalls and a bottom of the third trench and a third copper layer filling all remaining space in the third trench, the electromigration stop between and abutting respective ends of the first and second wires. | 09-18-2014 |
20140278247 | REMOTE ELECTROMIGRATION MONITORING OF ELECTRONIC CHIPS - A method of remotely monitoring electromigration in an electronic chip includes sensing, at a first location, at least one temperature value of the electronic chip, sending the at least one temperature value to a remote monitoring system, accumulating a plurality of temperature values of the electronic chip at the monitoring system during a reporting period, calculating an Electromigration Life Consumed (EMLC) value of the electronic chip for the reporting period based on the plurality of temperature values, determining whether the EMLC of the electronic chip is above a predetermined threshold, and providing a signal when the EMLC of the electronic chip is above the predetermined threshold. | 09-18-2014 |
20140319650 | PROGRAMMABLE ELECTRICAL FUSE - An method and structure of forming an electronic fuse. The method including forming a first metal line and a second metal line in a first interconnect level, wherein the first metal line is electrically insulated form the second metal line, and forming a via in a second interconnect level above the first interconnect level, the via electrically and physically connecting the first metal line with the second metal line. The via may create a sub-lithographic contact with the underlying metal line, thus increasing current density and probability of failure at a specific location. | 10-30-2014 |
20140380261 | SEMICONDUCTOR DEVICE RELIABILITY MODEL AND METHODOLOGIES FOR USE THEREOF - Systems and methods for semiconductor device reliability qualification during semiconductor device design. A method is provided that includes defining performance process window bins for a performance window. The method further includes determining at least one failure mechanism for each bin assignment. The method further includes generating different reliability models when the at least one failure mechanism is a function of the process window, and generating common reliability models when the at least one failure mechanism is not the function of the process window. The method further includes identifying at least one risk factor for each bin assignment, and generating aggregate models using a manufacturing line distribution. The method further includes determining a fail rate by bin and optimizing a line center to minimize product fail rate. The method further includes determining a fail rate by bin and scrapping production as a function of a manufacturing line excursion event. | 12-25-2014 |
20150016486 | REMOTE ELECTROMIGRATION MONITORING OF ELECTRONIC CHIPS - A method of remotely monitoring electromigration in an electronic chip includes sensing, at a first location, at least one temperature value of the electronic chip, sending the at least one temperature value to a remote monitoring system, accumulating a plurality of temperature values of the electronic chip at the monitoring system during a reporting period, calculating an Electromigration Life Consumed (EMLC) value of the electronic chip for the reporting period based on the plurality of temperature values, determining whether the EMLC of the electronic chip is above a predetermined threshold, and providing a signal when the EMLC of the electronic chip is above the predetermined threshold. | 01-15-2015 |
20150033081 | IN-SITU COMPUTING SYSTEM FAILURE AVOIDANCE - A remaining time to replace can be updated taking into account time variation of a failure mechanism of a device. Starting with an initial remaining time to replace, an effective operating time can be determined periodically based on an operating parameter measured at a tracking interval, and remaining time to replace can be updated by subtracting the effective operating time. The technique can be applied to multiple failure mechanisms and to multiple devices and/or components each having multiple failure mechanisms. | 01-29-2015 |
20150035158 | SEMICONDUCTOR DEVICES WITH ENHANCED ELECTROMIGRATION PERFORMANCE - Semiconductor devices with enhanced electromigration performance and methods of manufacture are disclosed. The method includes forming at least one metal line in electrical contact with a device. The method further includes forming at least one staple structure in electrical contact with the at least one metal line. The at least one staple structure is formed such that electrical current passing through the at least one metal line also passes through the at least staple structure to reduce electromigration issues. | 02-05-2015 |