Patent application number | Description | Published |
20120068315 | METHOD OF IMPROVING MECHANICAL PROPERTIES OF SEMICONDUCTOR INTERCONNECTS WITH NANOPARTICLES - In a BEOL process, UV radiation is used in a curing process of ultra low-k (ULK) dielectrics. This radiation penetrates through the ULK material and reaches the cap film underneath it. The interaction between the UV light and the film leads to a change the properties of the cap film. Of particular concern is the change in the stress state of the cap from compressive to tensile stress. This leads to a weaker dielectric-cap interface and mechanical failure of the ULK film. A layer of nanoparticles is inserted between the cap and the ULK film. The nanoparticles absorb the UV light before it can damage the cap film, thus maintaining the mechanical integrity of the ULK dielectric. | 03-22-2012 |
20120146224 | Semiconductor having interconnects with improved mechanical properties by insertion of nanoparticles - In a BEOL process, UV radiation is used in a curing process of ultra low-k (ULK) dielectrics. This radiation penetrates through the ULK material and reaches the cap film underneath it. The interaction between the UV light and the film leads to a change the properties of the cap film. Of particular concern is the change in the stress state of the cap from compressive to tensile stress. This leads to a weaker dielectric-cap interface and mechanical failure of the ULK film. A layer of nanoparticles is inserted between the cap and the ULK film. The nanoparticles absorb the UV light before it can damage the cap film, thus maintaining the mechanical integrity of the ULK dielectric. | 06-14-2012 |
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 |
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 |
20130176073 | BACK-END ELECTRICALLY PROGRAMMABLE FUSE - A BEOL e-fuse is disclosed which reliably blows in the via and can be formed even in the tightest pitch BEOL layers. The BEOL e-fuse can be formed utilizing a line first dual damascene process to create a sub-lithographic via to be the programmable link of the e-fuse. The sub-lithographic via can be patterned using standard lithography and the cross section of the via can be tuned to match the target programming current. | 07-11-2013 |
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 |
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 |
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 |
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 |
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 |
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 |
20150035115 | MODIFIED VIA BOTTOM FOR BEOL VIA EFUSE - An electronic fuse structure including an M | 02-05-2015 |