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 |
20080303164 | STRUCTURE AND METHOD OF REDUCING ELECTROMIGRATION CRACKING AND EXTRUSION EFFECTS IN SEMICONDUCTOR DEVICES - A structure for reducing electromigration cracking and extrusion effects in semiconductor devices includes a first metal line formed in a first dielectric layer; a cap layer formed over the first metal line and first dielectric layer; a second dielectric layer formed over the cap layer; and a void formed in the second dielectric layer, stopping on the cap layer, wherein the void is located in a manner so as to isolate structural damage due to electromigration effects of the first metal line, the effects including one or more of extrusions of metal material from the first metal line and cracks from delamination of the cap layer with respect to the first dielectric layer. | 12-11-2008 |
20080308942 | SEMICONDUCTOR WIRING STRUCTURES INCLUDING DIELECTRIC CAP WITHIN METAL CAP LAYER - Semiconductor wiring structures including a dielectric layer having a metal wiring line therein, a via extending downwardly from the metal wiring line, a metal cap layer over the metal wiring line, and a local dielectric cap positioned within a portion of the metal cap layer and in contact with the metal wiring line and a related method are disclosed. The local dielectric cap represents an intentionally created weak point in the metal wiring line of a dual-damascene interconnect, which induces electromigration (EM) voiding in the line, rather than at the bottom of a via extending downwardly from the metal wiring line. Since the critical void size in line fails, especially with metal cap layer (liner) redundancy, is much larger than that in via fails, the EM lifetime can be significantly increased. | 12-18-2008 |
20090033351 | TEST STRUCTURE FOR ELECTROMIGRATION ANALYSIS AND RELATED METHOD - A test structure for electromigration and related method are disclosed. The test structure may include an array of a plurality of multilink test sets, each multilink test set including a plurality of metal lines positioned within a dielectric material and connected in a serial configuration; each multilink test set being connected in a parallel configuration with the other multilink test sets, the parallel configuration including a first electrical connection to a cathode end of a first metal line in each multilink test set and a second electrical connection to an anode end of a last metal line in each multilink test set. | 02-05-2009 |
20090039896 | EXTRUSION FAILURE MONITOR STRUCTURES - A structure and method for monitoring extrusion failures. The structure includes: a test wire having first and second ends; first and second vias contacting first and second ends of the test wire; a first monitor structure electrically isolated from the test wire and surrounding a periphery of the test wire; and a second monitor structure over the test wire, the second monitor structure electrically isolated from the test wire, the second monitor structure extending over at least the first end of the test wire. | 02-12-2009 |
20090108855 | TEST STRUCTURE FOR ELECTROMIGRATION ANALYSIS AND RELATED METHOD - A test structure for electromigration and related method are disclosed. The test structure may include an array of a plurality of multilink test sets, each multilink test set including a plurality of metal lines positioned within a dielectric material and connected in a serial configuration; each multilink test set being connected in a parallel configuration with the other multilink test sets, the parallel configuration including a first electrical connection to a cathode end of a first metal line in each multilink test set and a second electrical connection to an anode end of a last metal line in each multilink test set. | 04-30-2009 |
20090146143 | TEST STRUCTURE FOR DETERMINING OPTIMAL SEED AND LINER LAYER THICKNESSES FOR DUAL DAMASCENE PROCESSING - A test structure for integrated circuit (IC) device fabrication includes a plurality of test structure chains formed at various regions of an IC wafer, each of the plurality of test structure chains including one or more vias; each of the one or more vias in contact with a conductive line disposed thereabove, the conductive line being configured such that at least one dimension thereof varies from chain to chain so as to produce variations in seed layer and liner layer thickness from chain to chain for the same deposition process conditions. | 06-11-2009 |
20090294901 | STRUCTURE AND METHOD OF FORMING ELECTRICALLY BLOWN METAL FUSES FOR INTEGRATED CIRCUITS - A fuse structure for an integrated circuit device includes an elongated metal interconnect layer defined within an insulating layer; a metal cap layer formed on only a portion of a top surface of the metal interconnect layer; and a dielectric cap layer formed on both the metal cap layer and the remaining portions of the metal interconnect layer not having the metal cap layer formed thereon; wherein the remaining portions of the metal interconnect layer not having the metal cap layer formed thereon are susceptible to an electromigration failure mechanism so as to facilitate programming of the fuse structure by application of electric current through the elongated metal interconnect layer. | 12-03-2009 |
20090294973 | INTERCONNECT STRUCTURE FOR INTEGRATED CIRCUITS HAVING IMPROVED ELECTROMIGRATION CHARACTERISTICS - An interconnect structure for an integrated circuit (IC) device includes an elongated, electrically conductive line comprising one or more segments formed at a first width, w | 12-03-2009 |
20090297759 | Stress Locking Layer for Reliable Metallization - Recrystallization and grain growth of metal, such as Cu, is achieved at higher anneal temperatures of 150° C. to 400° C., for example, for short anneal times of five to sixty minutes by forming a metal stress locking layer on the Cu before anneal and chemical-mechanical polishing. The stress locking layer extends the elastic region of the Cu by suppressing atom diffusion to the free surface, resulting in near zero tensile stress at room temperature after anneal. Stress voiding, which creates reliability problems, is thereby avoided. Improved grain size and texture are also achieved. The stress locking layer is removed after anneal by chemical-mechanical polishing leaving the Cu interconnect with low stress and improved grain size and texture. | 12-03-2009 |
20100038747 | ELECTRICALLY PROGRAMMABLE FUSE AND FABRICATION METHOD - An electrically programmable fuse includes an anode, a cathode, and a fuse link conductively connecting the cathode with the anode, which is programmable by applying a programming current. The anode and the fuse link each include a polysilicon layer and a silicide layer formed on the polysilicon layer, and the cathode includes the polysilicon layer and a partial silicide layer formed on a predetermined portion of the polysilicon layer of the cathode located adjacent to a cathode junction where the cathode and the fuse link meet. | 02-18-2010 |
20100038790 | RELIABILITY OF WIDE INTERCONNECTS - An integrated circuit which includes a semiconductor substrate, a first metal wiring level on the semiconductor substrate which includes metal wiring lines, an interconnect wiring level on the first metal wiring level which includes a via interconnect within an interlevel dielectric, a second metal wiring level on the interconnect wiring level which includes metal wiring lines, at least one metal wiring line having a plurality of dielectric fill shapes that reduces the cross sectional area of the at least one metal wiring line, and wherein the via interconnect makes electrical contact between a metal line in the first wiring level and the at least one metal wiring line in the second wiring level, the via interconnect being adjacent to and spaced from the plurality of dielectric fill shapes. Also disclosed is a method in which a plurality of dielectric fill shapes are placed adjacent to and spaced from a via contact area in a wiring line in a second wiring level. | 02-18-2010 |
20110186963 | ELECTRICALLY PROGRAMMABLE FUSE AND FABRICATION METHOD - An electrically programmable fuse includes an anode, a cathode, and a fuse link conductively connecting the cathode with the anode, which is programmable by applying a programming current. The anode and the fuse link each include a polysilicon layer and a silicide layer formed on the polysilicon layer, and the cathode includes the polysilicon layer and a partial silicide layer formed on a predetermined portion of the polysilicon layer of the cathode located adjacent to a cathode junction where the cathode and the fuse link meet. | 08-04-2011 |
20110254168 | INTEGRATED CIRCUIT INTERCONNECT STRUCTURE - An integrated circuit (IC) interconnect structure that includes a first via positioned in a dielectric and coupled to a high current device at one end, and a buffer metal segment positioned in a dielectric and coupled to the first via at an opposite end thereof. The buffer metal segment includes a plurality of electrically insulating inter-dielectric (ILD) pads forming an ILD cheesing pattern thereon, to direct current. The IC interconnect structure further includes a second via positioned in a dielectric formed over the buffer metal segment and coupled to the buffer metal segment at one end and a metal power line formed in a dielectric and coupled to the second via at an opposite end thereof. The use of the ILD pads on the buffer metal segment enables a more even distribution of current along the metal power line. | 10-20-2011 |
20120249159 | Stacked Via Structure For Metal Fuse Applications - A back end of the line (BEOL) fuse structure having a stack of vias. The stacking of vias leads to high aspect ratios making liner and seed coverage inside the vias poorer. The weakness of the liner and seed layers leads to a higher probability of electromigration (EM) failure. The fuse structure addresses failures due to poor liner and seed coverage. Design features permit determining where failures occur, determining the extent of the damaged region after fuse programming and preventing further propagation of the damaged dielectric region. | 10-04-2012 |
20120264289 | INTEGRATED CIRCUIT INTERCONNECT STRUCTURE - An integrated circuit (IC) interconnect structure that includes a first via positioned in a dielectric and coupled to a high current device at one end, and a buffer metal segment positioned in a dielectric and coupled to the first via at an opposite end thereof. The buffer metal segment includes a plurality of electrically insulating inter-dielectric (ILD) pads forming an ILD cheesing pattern thereon, to direct current. The IC interconnect structure further includes a second via positioned in a dielectric formed over the buffer metal segment and coupled to the buffer metal segment at one end and a metal power line formed in a dielectric and coupled to the second via at an opposite end thereof. The use of the ILD pads on the buffer metal segment enables a more even distribution of current along the metal power line. | 10-18-2012 |
20120264295 | STRUCTURE AND METHOD OF REDUCING ELECTROMIGRATION CRACKING AND EXTRUSION EFFECTS IN SEMICONDUCTOR DEVICES - A structure for reducing electromigration cracking and extrusion effects in semiconductor devices includes a first metal line formed in a first dielectric layer; a cap layer formed over the first metal line and first dielectric layer; a second dielectric layer formed over the cap layer; and a void formed in the second dielectric layer, stopping on the cap layer, wherein the void is located in a manner so as to isolate structural damage due to electromigration effects of the first metal line, the effects including one or more of extrusions of metal material from the first metal line and cracks from delamination of the cap layer with respect to the first dielectric layer. | 10-18-2012 |
20120273966 | INTEGRATED CIRCUIT INTERCONNECT STRUCTURE - An integrated circuit (IC) interconnect structure that includes a first via positioned in a dielectric and coupled to a high current device at one end, and a buffer metal segment positioned in a dielectric and coupled to the first via at an opposite end thereof. The buffer metal segment includes a plurality of electrically insulating inter-dielectric (ILD) pads forming an ILD cheesing pattern thereon, to direct current. The IC interconnect structure further includes a second via positioned in a dielectric formed over the buffer metal segment and coupled to the buffer metal segment at one end and a metal power line formed in a dielectric and coupled to the second via at an opposite end thereof. The use of the ILD pads on the buffer metal segment enables a more even distribution of current along the metal power line. | 11-01-2012 |
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 |
20120326269 | E-FUSE STRUCTURES AND METHODS OF MANUFACTURE - E-fuse structures in back end of the line (BEOL) interconnects and methods of manufacture are provided. The method includes forming an interconnect via in a substrate in alignment with a first underlying metal wire and forming an e-fuse via in the substrate, exposing a second underlying metal wire. The method further includes forming a defect with the second underlying metal wire and filling the interconnect via with metal and in contact with the first underlying metal wire thereby forming an interconnect structure. The method further includes filling the e-fuse via with the metal and in contact with the defect and the second underlying metal wire thereby forming an e-fuse structure. | 12-27-2012 |
20130127584 | Redundant Via Structure For Metal Fuse Applications - A metal fuse structure using redundant vias. The redundant vias are formed on one metal level in a stacked via metal fuse structure to force failures to occur in the metal level that does not have the redundant vias. The metal fuse structure includes: a first dielectric layer having a metal feature; a second dielectric layer having a first metal connector embedded therein; and a third dielectric layer having a second metal connector embedded therein. The metal connectors include at least one via and one line, and at least one metal connector has at least two vias. | 05-23-2013 |
20130214894 | METAL FUSE STRUCTURE FOR IMPROVED PROGRAMMING CAPABILITY - Structure providing more reliable fuse blow location, and method of making the same. A vertical metal fuse blow structure has, prior to fuse blow, an intentionally damaged portion of the fuse conductor. The damaged portion helps the fuse blow in a known location, thereby decreasing the resistance variability in post-blow circuits. At the same time, prior to fuse blow, the fuse structure is able to operate normally. The damaged portion of the fuse conductor is made by forming an opening in a cap layer above a portion of the fuse conductor, and etching the fuse conductor. Preferably, the opening is aligned such that the damaged portion is on the top corner of the fuse conductor. A cavity can be formed in the insulator adjacent to the damaged fuse conductor. The damaged fuse structure having a cavity can be easily incorporated in a process of making integrated circuits having air gaps. | 08-22-2013 |
20130234284 | Fuse and Integrated Conductor - A fuse structure includes within an aperture within a dielectric layer located over a substrate that exposes a conductor contact layer within the substrate a seed layer interposed between the conductor contact layer and another conductor layer. The seed layer includes a doped copper material that includes a dopant immobilized predominantly within the seed layer. The fuse structure may be severed while not severing a conductor interconnect structure also located over the substrate that exposes a second conductor contact layer within a second aperture. In contrast with the fuse structure that includes the doped seed layer having the immobilized dopant, the interconnect structure includes a doped seed layer having a mobile dopant. | 09-12-2013 |
20130307115 | ANTI-FUSE STRUCTURE AND FABRICATION - A method and structure of a non-intrinsic anti-fuse structure. The anti-fuse structure has a first electrode, a second electrode, a first dielectric, and second dielectric. The first and second dielectrics have an interface which couples electrodes. The length along the interface which couples the electrodes is called the predetermined length. When the anti-fuse is programmed a conductive link forms along the interface to connect the first and second electrodes. The anti-fuse structure can be single-level or dual-level. The predetermined length can be less than spacing between adjacent electrodes when a dual-level structure is used. The anti-fuse structures have the advantage that they can be programmed at lower voltages than intrinsic structures and no extra steps are needed to integrate the anti-fuses with active structures. | 11-21-2013 |
20130307151 | METHOD TO RESOLVE HOLLOW METAL DEFECTS IN INTERCONNECTS - A method of repairing hollow metal void defects in interconnects and resulting structures. After polishing interconnects, hollow metal void defects become visible. The locations of the defects are largely predictable. A repair method patterns a mask material to have openings over the interconnects (and, sometimes, the adjacent dielectric layer) where defects are likely to appear. A local metal cap is formed in the mask openings to repair the defect. A dielectric cap covers the local metal cap and any recesses formed in the adjacent dielectric layer. | 11-21-2013 |
20140028325 | STACKED VIA STRUCTURE FOR METAL FUSE APPLICATIONS - A back end of the line (BEOL) fuse structure having a stack of vias. The stacking of vias leads to high aspect ratios making liner and seed coverage inside the vias poorer. The weakness of the liner and seed layers leads to a higher probability of electromigration (EM) failure. The fuse structure addresses failures due to poor liner and seed coverage. Design features permit determining where failures occur, determining the extent of the damaged region after fuse programming and preventing further propagation of the damaged dielectric region. | 01-30-2014 |
20140070362 | E-FUSE STRUCTURES AND METHODS OF MANUFACTURE - E-fuse structures in back end of the line (BEOL) interconnects and methods of manufacture are provided. The method includes forming an interconnect via in a substrate in alignment with a first underlying metal wire and forming an e-fuse via in the substrate, exposing a second underlying metal wire. The method further includes forming a defect with the second underlying metal wire and filling the interconnect via with metal and in contact with the first underlying metal wire thereby forming an interconnect structure. The method further includes filling the e-fuse via with the metal and in contact with the defect and the second underlying metal wire thereby forming an e-fuse structure. | 03-13-2014 |
20140070363 | ELECTRONIC ANTI-FUSE - An electronic anti-fuse structure, the structure including an M | 03-13-2014 |
20140118020 | STRUCTURES AND METHODS FOR DETERMINING TDDB RELIABILITY AT REDUCED SPACINGS USING THE STRUCTURES - A structure for TDDB measurement, a method determining TDDB at reduced spacings. The structure includes an upper dielectric layer on a top surface of a lower dielectric layer, a bottom surface of the upper dielectric layer and the top surface of the lower dielectric layer defining an interface; a first wire formed in the lower dielectric layer; a second wire formed in the upper dielectric layer; and wherein a distance between the first wire and the second wire measured in a direction parallel to the interface is below the lithographic resolution limit of the fabrication technology. | 05-01-2014 |
20140167268 | GRAPHENE AND METAL INTERCONNECTS - A graphene and metal interconnect structure and methods of making the same are disclosed. The graphene is a multiple layer graphene structure that is grown using a graphene catalyst. The graphene forms an electrical connection between two or more VIAs or components, or a combination of VIAs and components. A VIA includes a fill metal, with at least a portion of the fill metal being surrounded by a barrier metal. A component may be a routing track, a clock signal source, a power source, an electromagnetic signal source, a ground terminal, a transistor, a macrocell, or a combination thereof. The graphene is grown, using a graphene catalyst, from both solid and liquid carbon sources using chemical vapor deposition (CVD) at a temperature between 300° C.-400° C. The graphene catalyst can be an elemental form of, or alloy including, nickel, palladium, ruthenium, iridium or copper. | 06-19-2014 |
20140167772 | STACKED VIA STRUCTURE FOR METAL FUSE APPLICATIONS - A back end of the line (BEOL) fuse structure having a stack of vias. The stacking of vias leads to high aspect ratios making liner and seed coverage inside the vias poorer. The weakness of the liner and seed layers leads to a higher probability of electromigration (EM) failure. The fuse structure addresses failures due to poor liner and seed coverage. Design features permit determining where failures occur, determining the extent of the damaged region after fuse programming and preventing further propagation of the damaged dielectric region. | 06-19-2014 |
20140183688 | MODIFIED VIA BOTTOM FOR BEOL VIA EFUSE - An electronic fuse structure including an M | 07-03-2014 |
20140203435 | SELECTIVE LOCAL METAL CAP LAYER FORMATION FOR IMPROVED ELECTROMIGRATION BEHAVIOR - A method of forming a wiring structure for an integrated circuit device includes forming one or more copper lines within an interlevel dielectric layer (ILD); masking selected regions of the one or more copper lines; selectively plating metal cap regions over exposed regions of the one or more copper lines; and forming a conformal insulator layer over the metal cap regions and uncapped regions of the one or more copper lines. | 07-24-2014 |
20140203436 | SELECTIVE LOCAL METAL CAP LAYER FORMATION FOR IMPROVED ELECTROMIGRATION BEHAVIOR - A method of forming a wiring structure for an integrated circuit device includes forming a first metal line within an interlevel dielectric (ILD) layer, and forming a second metal line in the ILD layer adjacent the first metal line; masking selected regions of the first and second metal lines; selectively plating metal cap regions over exposed regions of the first and second metal lines at periodic intervals such that a spacing between adjacent metal cap regions of an individual metal line corresponds to a critical length, L, at which a back stress gradient balances an electromigration force in the individual metal line, so as to suppress mass transport of electrons; and wherein the metal cap regions of the first metal line are formed at staggered locations with respect to the metal cap regions of the second metal line, along a common longitudinal axis. | 07-24-2014 |
20140210040 | ELECTRONIC FUSE LINE WITH MODIFIED CAP - An electronic fuse structure having an M | 07-31-2014 |
20140217612 | ELECTRONIC FUSE HAVING A DAMAGED REGION - An electronic fuse structure including an M | 08-07-2014 |
20140252538 | ELECTRONIC FUSE WITH RESISTIVE HEATER - A method of forming an electronic fuse including forming an M | 09-11-2014 |
20140319685 | Hybrid Graphene-Metal Interconnect Structures - Hybrid metal-graphene interconnect structures and methods of forming the same. The structure may include a first end metal, a second end metal, a conductive line including one or more graphene portions extending from the first end metal to the second end metal, and one or more line barrier layers partially surrounding each of the one or more graphene portions. The conductive line may further include one or more intermediate metals separating each of the one or more graphene portions. Methods of forming said interconnect structures may include forming a plurality of metals including a first end metal and a second end metal in a dielectric layer, forming one or more line trenches between each of the plurality of metals, forming a line barrier layer in each of the one or more line trenches, and filling the one or more line trenches with graphene. | 10-30-2014 |
20140332923 | E-FUSE WITH HYBRID METALLIZATION - An e-fuse structure including a fuse link having a first region made of a first conductor and a second region made of a second conductor. The first conductor and the second conductor are in the same wiring level. The first conductor has a higher electrical resistance than the second conductor. The first conductor has a higher resistance to electromigration than the second conductor. The first region and the second region have a common width. The length of the first region is longer than the length of the second region. | 11-13-2014 |
20140332924 | E-FUSE WITH HYBRID METALLIZATION - A structure including a first interconnect including a first line overlying a first via and a second interconnect including a second line overlying a second via. The first line and the second line are co-planar. The first interconnect comprises a first conductor, the first conductor comprises a metal silicide including titanium silicide, cobalt silicide, nickel silicide, tungsten silicide, platinum silicide, molybdenum silicide, tantalum silicide, or some combination thereof. The second interconnect comprises a second conductor, the second conductor comprising copper. | 11-13-2014 |
20140332963 | INTERCONNECT WITH HYBRID METALLIZATION - An electronic interconnect structure having a hybridized metal structure near regions of high operating temperature on an integrated circuit, and methods of making the same. The hybridized metal structure features at least two different metals in a single metallization level. The first metal is in a region of high operating temperature and the second region is in a region of normal operating temperatures. In a preferred embodiment the first metal includes aluminum and is in a first level metallization over an active area of the device while the second metal includes copper. In some embodiments, the first and second metals are not in direct physical contact. In other embodiments the first and second metals physically contact each other. In a preferred embodiment, a top surface of the first metal is not co-planar with a top surface of the second metal, despite being in the same metallization level. | 11-13-2014 |
20140332965 | High Performance Refractory Metal / Copper Interconnects To Eliminate Electromigration - An interconnect structure and method of making the same. A preferred interconnect structure has a first interconnect including a first dual damascene via and narrow line and a second interconnect at the same level as the first including a second dual damascene via and wider line. The first and second interconnects may have different aspect ratio and may have different line heights while being co-planar with each other. The second line of the second interconnect may abut or partially surround the first line of the first interconnect. The first interconnect includes a refractory metal material as the main conductor, whereas the second interconnect includes a lower resistivity material as its main conductor. | 11-13-2014 |
20140346674 | GRAPHENE-METAL E-FUSE - A structure including an M | 11-27-2014 |
20150021736 | ELECTRONIC FUSE LINE WITH MODIFIED CAP - An electronic fuse structure having an M | 01-22-2015 |
20150028484 | RANDOM LOCAL METAL CAP LAYER FORMATION FOR IMPROVED INTEGRATED CIRCUIT RELIABILITY - A method and structure for preventing integrated circuit failure due to electromigration and time dependent dielectric breakdown is disclosed. A randomly patterned metal cap layer is selectively formed on the metal interconnect lines (typically copper (Cu)) with an interspace distance between metal cap segments that is less than the critical length (for short-length effects). Since the diffusivity is lower for the Cu/metal cap interface than for the Cu/dielectric cap interface, the region with a metal cap serves as a diffusion barrier. | 01-29-2015 |
20150035115 | MODIFIED VIA BOTTOM FOR BEOL VIA EFUSE - An electronic fuse structure including an M | 02-05-2015 |
20150041951 | ELECTRONIC FUSE VIAS IN INTERCONNECT STRUCTURES - An electronic fuse and method for forming the same. Embodiments of the invention include e-fuses having a first metallization level including a metal structure, a second metallization level above the first metallization level, a metal via in the second metallization level, an interface region where the metal via meets the first metallization level, and a damaged region at the interface region. Embodiments further include a method including providing a first metallization level including a metal structure, forming a capping layer on the first metallization level, forming an opening in the capping layer that exposes a portion of the metal structure; forming above the capping layer an adhesion layer contacting the metal structure, forming an insulating layer above the adhesion layer, etching the insulating layer and the adhesion layer to form a recess exposing the metal structure, and filling the fuse via recess to form a fuse via. | 02-12-2015 |
20150056806 | INTERCONNECT STRUCTURE WITH ENHANCED RELIABILITY - An improved interconnect structure including a dielectric layer having a conductive feature embedded therein, the conductive feature having a first top surface that is substantially coplanar with a second top surface of the dielectric layer; a metal cap layer located directly on the first top surface, wherein the metal cap layer does not substantially extend onto the second top surface; a first dielectric cap layer located directly on the second top surface, wherein the first dielectric cap layer does not substantially extend onto the first top surface and the first dielectric cap layer is thicker than the metal cap layer; and a second dielectric cap layer on the metal cap layer and the first dielectric cap layer. A method of forming the interconnect structure is also provided. | 02-26-2015 |