Patent application number | Description | Published |
20120178189 | METHOD FOR FORMING AN OVER PAD METALIZATION (OPM) ON A BOND PAD - A method of making a semiconductor structure includes forming a bond pad, depositing by laser defined deposition a conductive pad, and attaching an electrical connector to the conductive pad. The bond pad is a portion of an integrated circuit. The bond pad includes an exposed portion. The bond pad functions as a contact to the integrated circuit. The conductive pad is deposited on the exposed portion and is confined within a bond pad region around the exposed portion of the bond pad | 07-12-2012 |
20120299190 | METHODS AND APPARATUS TO IMPROVE RELIABILITY OF ISOLATED VIAS - A method for tiling selected vias in a semiconductor device is provided. The semiconductor device includes a plurality of vias. The method includes: generating a layout database for the semiconductor device; identifying isolated vias of the plurality of vias; selecting the isolated vias; defining a zone around each of the selected isolated vias; and adding tiling features on a metal layer above the selected isolated vias and within the zone. The method improves reliability of the semiconductor device by allowing moisture to vent from around the vias. | 11-29-2012 |
20130105986 | SEMICONDUCTOR DEVICE WITH VIAS ON A BRIDGE CONNECTING TWO BUSES | 05-02-2013 |
20130127064 | METHOD AND APPARATUS TO IMPROVE RELIABILITY OF VIAS - In a disclosed embodiment, a method for tiling selected vias in a semiconductor device having a plurality of vias comprises generating a layout database for the semiconductor device; creating zones around the plurality of vias; measuring density of covering metal in each zone; selecting a low density zone as being a zone that has a metal density less than a threshold metal density; and adding at least one tiling feature on a metal layer above the plurality of vias in the low density zone so that metal density of the low density zone increases to at least the same as the threshold metal density. | 05-23-2013 |
20130134595 | METHODS AND APPARATUS TO IMPROVE RELIABILITY OF ISOLATED VIAS - A method for increasing metal density around selected vias in a semiconductor device is provided. The semiconductor device includes a plurality of vias. The method includes: generating a layout database for the semiconductor device; identifying isolated vias of the plurality of vias; selecting the isolated vias; defining a zone around each of the selected isolated vias; and increasing area of a metal layer which is above the selected isolated via and which encloses the selected isolated via within each zone to achieve a target metal density within the zone. The method improves reliability of the semiconductor device by allowing moisture to vent from around the vias. | 05-30-2013 |
20130147051 | METHOD OF PROTECTING AGAINST VIA FAILURE AND STRUCTURE THEREFOR - A method is for forming a decoy via and a functional via. The method includes forming the functional via between a metal portion of a first interconnect layer and a portion of a second interconnect layer. The method further includes forming the decoy via in a protection region between the metal portion of the first interconnect layer and a metal portion of the third interconnect level. | 06-13-2013 |
20130187274 | SEMICONDUCTOR DEVICE HAVING A NANOTUBE LAYER AND METHOD FOR FORMING - A method of forming a semiconductor device includes forming a first conductive layer over the substrate. A dielectric layer, having a first opening, is formed over the first conductive layer. A seed layer is deposited over the first dielectric layer and in the first opening. A layer is formed of conductive nanotubes from the seed layer over the first dielectric layer and over the first opening. A second dielectric is formed over the layer of conductive nanotubes. An opening is formed in the second dielectric layer over the first opening. Conductive material is deposited in the second opening. | 07-25-2013 |
20130264698 | SEMICONDUCTOR DEVICE WITH HEAT DISSIPATION - A semiconductor assembly includes a semiconductor device and a connecting structure. The semiconductor device includes an interconnect region over a semiconductor substrate and a pillar layer having a plurality of pillar contacts on the interconnect region. The pillar layer also includes a plurality of radial heat conductors that have at least a portion overlying a heat source that is within and overlies the semiconductor substrate. Each radial heat conductor extends a length radially from the heat source that is at least twice as great as the diameter of the pillars. The connecting structure includes a connecting substrate that supports a first corresponding pillar contact that is in contact with a first pillar contact of the plurality of pillar contacts. The first connecting structure further includes a heat conductor, supported by the substrate, in contact with a first radial heat conductor of the plurality of radial heat conductors. | 10-10-2013 |
20130264700 | SEMICONDUCTOR DEVICE WITH EMBEDDED HEAT SPREADING - A semiconductor device includes a semiconductor substrate and a plurality of clock drivers, wherein the plurality of clock drivers comprises substantially all clock drivers of the semiconductor device, and an interconnect region over the semiconductor substrate, wherein the interconnect region comprises a plurality of heat spreaders, wherein at least 25% of the plurality of clock drivers have a corresponding heat spreader of the plurality of heat spreaders. Each corresponding heat spreader of the plurality of heat spreaders covers at least 50% of a transistor within a corresponding clock driver of the plurality of clock drivers and extends across at least 70% of a perimeter of the transistor within the corresponding clock driver. | 10-10-2013 |
20130326446 | TECHNIQUES FOR CHECKING COMPUTER-AIDED DESIGN LAYERS OF A DEVICE TO REDUCE THE OCCURRENCE OF MISSING DECK RULES - A technique for computer-aided design layer checking of an integrated circuit design includes generating a representation of a device (e.g., a parameterized cell). Computer-aided design (CAD) layers are sequentially removed from the parameterized cell and a determination is made as to whether expected errors are detected or missed by an associated deck. The associated deck is then modified to detect the expected errors that are missed. | 12-05-2013 |
20140038317 | METHOD FOR FORMING AN ELECTRICAL CONNECTION BETWEEN METAL LAYERS - A method forms an electrical connection between a first metal layer and a second metal layer. The second metal layer is above the first metal layer. A first via is formed between the first metal layer and the second metal layer. A first measure of a number of vacancies expected to reach the first via is obtained. A second via in at least one of the first metal layer and the second metal layer is formed if the measure of vacancies exceeds a first predetermined number. | 02-06-2014 |
20140038319 | METHOD FOR FORMING AN ELECTRICAL CONNECTION BETWEEN METAL LAYERS - A method includes forming a connection between a first metal layer and a second metal layer. The second metal layer is over the first metal layer. A via location for a first via between the first metal layer and the second metal layer is identified. Additional locations for first additional vias are determined. The first additional vias are determined to be necessary for stress migration issues. Additional locations necessary for second additional vias are determined. The second additional vias are determined to be necessary for electromigration issues. The first via and the one of the group consisting of (i) the first additional vias and second additional vias (ii) the first additional vias plus a number of vias sufficient for electromigration issues taking into account that the first additional vias, after taking into account the stress migration issues, still have an effective via number greater than zero. | 02-06-2014 |
20140040839 | METHOD AND SYSTEM FOR DERIVED LAYER CHECKING FOR SEMICONDUCTOR DEVICE DESIGN - A system and method are provided for enabling a systematic detection of issues arising during the course of mask generation for a semiconductor device. IC mask layer descriptions are analyzed and information is generated that identifies devices formed by active layers in the masks, along with a description of all layers in proximity to the found devices. The IC mask information is compared to a netlist file generated from the initial as-designed schematic. Determinations can then made, for example, as to whether all intended devices are present, any conflicting layers are in proximity to or interacting with the intended devices, and any unintended devices are present in the mask layers. Steps can then be taken to resolve the issues presented by the problematic devices. | 02-06-2014 |
20140091475 | METHOD AND APPARATUS TO IMPROVE RELIABILITY OF VIAS - A semiconductor device comprising a first insulating layer, a first metal conductor layer formed over the first insulating layer, a second insulating layer comprising a low-k insulating material formed over the first metal conductor, a second metal conductor layer formed over the second insulating layer, vias formed in the second insulating layer connecting the first metal conductor layer to the second metal conductor layer, and a plurality of metal lines. One of the metal lines is expanded around one of the vias compared to metal lines around other ones of the vias so that predetermined areas around each of the vias meets a minimum metal density. | 04-03-2014 |
20140094029 | METHOD FOR FORMING AN ELECTRICAL CONNECTION BETWEEN METAL LAYERS - A method includes forming a connection between a first metal layer and a second metal layer. The second metal layer is over the first metal layer. A via location for a first via between the first metal layer and the second metal layer is identified. Additional locations for first additional vias are determined. The first additional vias are determined to be necessary for stress migration issues. Additional locations necessary for second additional vias are determined. The second additional vias are determined to be necessary for electromigration issues. The first via and the one of the group consisting of (i) the first additional vias and second additional vias (ii) the first additional vias plus a number of vias sufficient for electromigration issues taking into account that the first additional vias, after taking into account the stress migration issues, still have an effective via number greater than zero. | 04-03-2014 |
20140239440 | Thin Beam Deposited Fuse - A back-end-of-line thin ion beam deposited fuse ( | 08-28-2014 |
20140258582 | SEMICONDUCTOR DEVICE WITH VIAS ON A BRIDGE CONNECTING TWO BUSES - A semiconductor device comprises conductive buses and conductive bridges. A respective conductive bridge is conductively coupled to at least two portions of at least one of the conductive buses. At least N plus one (N+1) vias are coupled between every one of the conductive bridges and a respective feature in an integrated circuit when: (1) a width of the respective conductive bridge is less than a width of each of the at least two portions of the at least one of the conductive buses to which the respective conductive bridge is coupled, and (2) a distance along the respective conductive bridge and at least one of the vias is less than a critical distance. N is a number of conductive couplings between the respective one of the conductive bridges and the at least one of the conductive buses. | 09-11-2014 |
20140329383 | SEMICONDUCTOR DEVICE WITH EMBEDDED HEAT SPREADING - A semiconductor device includes a semiconductor substrate and a plurality of clock drivers, wherein the plurality of clock drivers comprises substantially all clock drivers of the semiconductor device, and an interconnect region over the semiconductor substrate, wherein the interconnect region comprises a plurality of heat spreaders, wherein at least 25% of the plurality of clock drivers have a corresponding heat spreader of the plurality of heat spreaders. Each corresponding heat spreader of the plurality of heat spreaders covers at least 50% of a transistor within a corresponding clock driver of the plurality of clock drivers and extends across at least 70% of a perimeter of the transistor within the corresponding clock driver. | 11-06-2014 |
20140353797 | FUSE/RESISTOR UTILIZING INTERCONNECT AND VIAS AND METHOD OF MAKING - A semiconductor structure comprising a fuse/resistor structure over a functional layer having a substrate. The fuse/resistor structure includes a via, a first interconnect layer, and a second interconnect layer. The via is over the functional layer and has a first end and a second end vertically opposite the first end, wherein the first end is bounded by a first edge and a second edge opposite the first edge and the second end is bounded by a third edge and a fourth edge opposite the third edge. The first interconnect layer includes a first metal layer running horizontally and contacting the first end and completely extending from the first edge to the second edge. The second interconnect layer includes a second metal layer running horizontally and contacting the second end of the via and extending past the third edge but reaching less than half way to the fourth edge. | 12-04-2014 |
20140353841 | METHOD FOR FORMING AN ELECTRICAL CONNECTION BETWEEN METAL LAYERS - A method of making a semiconductor device having a substrate includes forming a first interconnect layer over the substrate, wherein a first metal portion of a first metal type is within the first interconnect layer and has a first via interface location. An interlayer dielectric is formed over the first interconnect layer. An opening in the interlayer dielectric is formed over the via interface location of the first metal portion. A second interconnect layer is formed over the interlayer dielectric. A second metal portion and a via of the first metal type is within the second interconnect layer. The via is formed in the opening to form an electrical contact between the first metal portion and the second metal portion. The via is over the first via interface location. A first implant of the first metal type is aligned to the first via interface location. | 12-04-2014 |
20150035151 | Capping Layer Interface Interruption for Stress Migration Mitigation - A semiconductor device includes a substrate, a dielectric layer supported by the substrate, an interconnect adjacent the dielectric layer, the interconnect including a conduction material and a barrier material disposed along sidewalls of the interconnect between the conduction material and the dielectric layer, and a layer disposed over the interconnect to establish an interface between the conduction material, the barrier material, and the layer. A plate is disposed along a section of the interconnect to interrupt the interface. | 02-05-2015 |
20150040092 | Stress Migration Mitigation - A computer-implemented method of configuring a semiconductor device includes identifying an interconnect having an interconnect path length greater than a stress-induced void formation characteristic length of the semiconductor device, and placing, with a processor, a conductive structure adjacent the interconnect to define a pair of segments of the interconnect. Each segment has a length no greater than the stress-induced void formation characteristic length of the interconnect, and the conductive structure is selected from the group consisting of a decoy via connected to the interconnect, a floating tile disposed along the interconnect, a tab that laterally extends outward from the interconnect, and a jumper from a first metal layer in which the interconnect is disposed to a second metal layer. | 02-05-2015 |
20150061709 | METHOD FOR FORMING A PACKAGED SEMICONDUCTOR DEVICE - A method of fabricating a packaged semiconductor device includes integrating a plurality of singulated semiconductor die in a die carrier, and forming one or more interconnect layers on the die carrier. The interconnect layers include at least one of conductive intra-layer structures and inter-layer structures coupled to contact pads on the plurality of singulated semiconductor die. A set of landing pads is formed coupled to a first subset of the contact pads via a first set of the conductive intra-layer structures and inter-layer structures. A set of probe pads is formed coupled to a second subset of the contact pads via a second set of the conductive intra-layer structures and inter-layer structures. The die carrier is singulated to form a plurality of packaged semiconductor devices. The set of probe pads is removed during the singulating the die carrier. | 03-05-2015 |
20150091160 | 3D DEVICE PACKAGING USING THROUGH-SUBSTRATE POSTS - A method for 3D device packaging utilizes through-substrate metal posts to mechanically and electrically bond two or more dice. The first die includes a set of access holes extending from a surface of the first die to a set of pads at a metal layer of the first die. The second die includes a set of metal posts. The first die and the second die are stacked such that each metal post extends from a surface of the second die toward a corresponding pad via a corresponding access hole. The first die and second die are mechanically and electrically bonded via solder joints formed between the metal posts and the corresponding pads. | 04-02-2015 |
20150091178 | 3D DEVICE PACKAGING USING THROUGH-SUBSTRATE PILLARS - A method for 3D device packaging utilizes through-substrate pillars to mechanically and electrically bond two or more dice. The first die includes a set of access holes extending from a surface of the first die to a set of pads at a metal layer of the first die. The second die includes a set of metal pillars. The first die and the second die are stacked such that each metal pillar extends from a surface of the second die to a corresponding pad via a corresponding access hole. The first die and second die are mechanically and electrically bonded via solder joints formed between the metal pillars and the corresponding pads. | 04-02-2015 |
20150091187 | 3D DEVICE PACKAGING USING THROUGH-SUBSTRATE POSTS - A method for 3D device packaging utilizes through-hole metal post techniques to mechanically and electrically bond two or more dice. The first die includes a set of through-holes extending from a first surface of the first die to a second surface of the first die. The second die includes a third surface and a set of metal posts. The first die and the second die are stacked such that the third surface of the second die faces the second surface of the first die, and each metal post extends through a corresponding through-hole to a point beyond the first surface of the first die, electrically coupling the first die and the second die. | 04-02-2015 |
20150137311 | Thin Beam Deposited Fuse - A back-end-of-line thin ion beam deposited fuse ( | 05-21-2015 |
20150178438 | SEMICONDUCTOR MANUFACTURING USING DESIGN VERIFICATION WITH MARKERS - A first circuit design is entered in an electronic design automation (EDA) computer system. The first circuit design includes a first feature with a first node. A marker is associated with the first node and represents a voltage associated with the first node as an algebraic expression of a numerical value representing a property of the circuit design. The marker is used to determine if the component of the circuit design violates a design rule. | 06-25-2015 |
20150200146 | Semiconductor Manufacturing Using Disposable Test Circuitry Within Scribe Lanes - Embodiments are disclosed for semiconductor manufacturing using disposable test circuitry formed within scribe lanes. The manufacturing steps can include forming device circuitry within a semiconductor die and forming test circuitry within a scribe lane. One or more electrical connection route lines are also formed that connect the device circuitry and test circuitry blocks. Further, each die can be connected to a single test circuitry block, or multiple dice can share common test circuitry blocks. After testing, the electrical connection route line(s) are sealed, and the test circuitry is discarded when the device dice are singulated. For certain embodiments, the edge of the devices dice are encapsulated with a protective metal layer, and certain other embodiments include protective sealrings through which the connection route lines pass to enter the dice from the test circuitry blocks within the scribe lanes. | 07-16-2015 |
20150206843 | SEMICONDUCTOR DEVICE HAVING A NANOTUBE LAYER AND METHOD FOR FORMING - A method of forming a semiconductor device includes forming a first conductive layer over the substrate. A dielectric layer, having a first opening, is formed over the first conductive layer. A seed layer is deposited over the first dielectric layer and in the first opening. A layer is formed of conductive nanotubes from the seed layer over the first dielectric layer and over the first opening. A second dielectric is formed over the layer of conductive nanotubes. An opening is formed in the second dielectric layer over the first opening. Conductive material is deposited in the second opening. | 07-23-2015 |
20150249048 | STRESS MIGRATION MITIGATION UTILIZING INDUCED STRESS EFFECTS IN METAL TRACE OF INTEGRATED CIRCUIT DEVICE - An integrated circuit (IC) device includes a plurality of metal layers having metal traces, and a plurality of vias interconnecting the metal traces. The presence of vacancies within the metal layers may disrupt the functionality of the IC device if the vacancies migrate to the vias interconnecting the metal layers. To mitigate vacancy migration, stressor elements are formed at the metal traces to form stress effects in the metal traces that, depending on type, either serve to repel migrating vacancies from the via contact area or to trap migrating vacancies at a portion of the metal trace displaced from the contact area. The stressor elements may be formed as stress-inducing dielectric or conductive material overlying the metal traces, or formed by inducing a stress memory effect in a portion of the metal trace itself. | 09-03-2015 |
20150348898 | APPARATUS AND METHOD FOR PLACING STRESSORS WITHIN AN INTEGRATED CIRCUIT DEVICE TO MANAGE ELECTROMIGRATION FAILURES - A method for selecting locations within an integrated circuit device for placing stressors to manage electromigration failures includes calculating an electric current for an interconnect within the integrated circuit device and determining an electromigration stress profile for the interconnect based on the electric current. The method further includes determining an area on the interconnect for placing a stressor to alter the electromigration stress profile for the interconnect. | 12-03-2015 |
20160064294 | SEMICONDUCTOR MANUFACTURING FOR FORMING BOND PADS AND SEAL RINGS - An integrated circuit die includes a first bond pad having a bond contact area at a first depth into a plurality of build-up layers over a semiconductor substrate of the integrated circuit die, having sidewalls that surround the bond contact area, the sidewalls extending from the first depth to a top surface of the plurality of build-up layers, and having a top portion that extends over a portion of a top surface of the plurality of build-up layers. | 03-03-2016 |
20160064324 | SEMICONDUCTOR PACKAGE WITH EMBEDDED CAPACITOR AND METHODS OF MANUFACTURING SAME - A semiconductor package with an embedded capacitor and corresponding manufacturing methods are described. The semiconductor package with the embedded capacitor includes a semiconductor die having a first metal layer extending across at least a portion of a first side of the semiconductor die and a package structure formed on the first side of the semiconductor die. A first electrical conductor of the embedded capacitor is formed in the first metal layer of the semiconductor die. The package structure includes a second metal layer that has formed therein a second electrical conductor of the embedded capacitor. A dielectric of the embedded capacitor is positioned within either the semiconductor die or the package structure of the semiconductor package to isolate the first electrical conductor from the second electrical conductor of the embedded capacitor. | 03-03-2016 |
20160093549 | INTEGRATED CIRCUIT HEATER FOR REDUCING STRESS IN THE INTEGRATED CIRCUIT MATERIAL AND CHIP LEADS OF THE INTEGRATED CIRCIT, AND FOR OPTIMIZING PERFORMANCE OF DEVICES OF THE INTEGRATED CIRCUIT - A device comprising a first detector, comprising an output, disposed at a first location of an integrated circuit chip and configured to determine a first temperature information, a chip heater, comprising an input to receive a control signal, disposed at a second location of the integrated circuit and configured to heat an area of the integrated circuit device that includes the first location and the second location, based upon the control signal, and a heater controller comprising a first input coupled to the output of the first detector to receive the first temperature information, and an output coupled to the input of the chip heater, the heater controller configured to generate the control signal based upon the first temperature information. | 03-31-2016 |
20160098510 | Integrated Circuit Design Using Pre-Marked Circuit Element Object Library - This disclosure describes an approach to create a library of pre-marked circuit element objects and use the pre-marked circuit element object library to design and fabricate an integrated circuit. Each of the circuit element objects are “pre-marked” and include embedded voltage markers having independent pre-assigned voltage values for each terminal in the circuit element object. When a circuit designer inserts a pre-marked circuit element object in a schematic design, the design tool determines whether each of the circuit element object terminal's pre-assigned voltage values match their corresponding nets to which they are connected. When the circuit designer completes the schematic design that includes valid nets throughout the schematic design, the design tool generates a layout design from the schematic design. The design tool, in turn, generates mask layer data from the layout design when the layout design passes verification testing. | 04-07-2016 |