| Patent application number | Description | Published |
|---|
| 20080217733 | ELECTRICAL FUSE STRUCTURE FOR HIGHER POST-PROGRAMMING RESISTANCE - The present invention provides an electrical fuse structure for achieving a post-programming resistance distribution with higher resistance values and to enhance the reliability of electrical fuse programming. A partly doped electrical fuse structure with undoped semiconductor material in the cathode combined with P-doped semiconductor material in the fuselink and anode is disclosed and the data supporting the superior performance of the disclosed electrical fuse is shown. | 09-11-2008 |
| 20080285335 | PROGRAMMABLE FUSE/NON-VOLATILE MEMORY STRUCTURES USING EXTERNALLY HEATED PHASE CHANGE MATERIAL - A programmable phase change material (PCM) structure includes a heater element formed at a transistor gate level of a semiconductor device, the heater element further including a pair of electrodes connected by a thin wire structure with respect to the electrodes, the heater element configured to receive programming current passed therethrough, a layer of phase change material disposed on top of a portion of the thin wire structure, and sensing circuitry configured to sense the resistance of the phase change material. | 11-20-2008 |
| 20090159948 | TRENCH METAL-INSULATOR METAL (MIM) CAPACITORS - The present invention relates to a semiconductor device that contains a trench metal-insulator-metal (MIM) capacitor and a field effect transistor (FET), and a design structure including the semiconductor device embodied in a machine readable medium. The trench MIM capacitor comprises a first metallic electrode layer located over interior walls of a trench in a substrate, a dielectric layer located in the trench over the first metallic electrode layer, and a second metallic electrode layer located in the trench over the dielectric layer. The FET comprises a source region, a drain region, a channel region between the source and drain regions, and a gate electrode over the channel region. The trench MIM capacitor is connected to the FET by a metallic strap. The semiconductor device of the present invention can be fabricated by a process in which the trench MIM capacitor is formed after the FET source/drain region but before the FET source/drain metal silicide contacts, for minimizing metal contamination in the FET. | 06-25-2009 |
| 20090267179 | SYSTEM FOR POWER PERFORMANCE OPTIMIZATION OF MULTICORE PROCESSOR CHIP - A system in one embodiment includes a multiprocessor chip comprising a plurality of cores; a plurality of power circuits, each power circuit being coupled to one of the cores; and an electrically programmable fuse in each power circuit. Each electrically programmable fuse further comprises a first electrode coupled to the associated power circuit; a second electrode coupled to the associated power circuit; a first pad coupled to the first electrode; a second pad coupled to the second electrode; and an electrically conductive material extending between the first and second electrodes and forming part of the associated power circuit, the electrically conductive material being characterized as tending to electromigrate from one of the electrodes to the other electrode under an applied electrical current passing between the electrodes, wherein the electromigration increases an overall resistance of the power circuit. | 10-29-2009 |
| 20100044826 | 3D INTEGRATED CIRCUIT DEVICE FABRICATION WITH PRECISELY CONTROLLABLE SUBSTRATE REMOVAL - A method is provided for fabricating a 3D integrated circuit structure. According to the method, a first active circuitry layer wafer is provided. The first active circuitry layer wafer comprises a P+ portion covered by a P− layer, and the P− layer includes active circuitry. The first active circuitry layer wafer is bonded face down to an interface wafer that includes a first wiring layer, and then the P+ portion of the first active circuitry layer wafer is selectively removed with respect to the P− layer of the first active circuitry layer wafer. Next, a wiring layer is fabricated on the backside of the P− layer. Also provided are a tangible computer readable medium encoded with a program for fabricating a 3D integrated circuit structure, and a 3D integrated circuit structure. | 02-25-2010 |
| 20100047964 | 3D INTEGRATED CIRCUIT DEVICE FABRICATION USING INTERFACE WAFER AS PERMANENT CARRIER - A method is provided for fabricating a 3D integrated circuit structure. Provided are an interface wafer including a first wiring layer and through-silicon vias, and a first active circuitry layer wafer including active circuitry. The first active circuitry layer wafer is bonded to the interface wafer. Then, a first portion of the first active circuitry layer wafer is removed such that a second portion remains attached to the interface wafer. A stack structure including the interface wafer and the second portion of the first active circuitry layer wafer is bonded to a base wafer. Next, the interface wafer is thinned so as to form an interface layer, and metallizations coupled through the through-silicon vias in the interface layer to the first wiring layer are formed on the interface layer. Also provided is a tangible computer readable medium encoded with a program that comprises instructions for performing such a method. | 02-25-2010 |
| 20100264551 | THREE DIMENSIONAL INTEGRATED CIRCUIT INTEGRATION USING DIELECTRIC BONDING FIRST AND THROUGH VIA FORMATION LAST - A method of implementing three-dimensional (3D) integration of multiple integrated circuit (IC) devices includes forming a first insulating layer over a first IC device; forming a second insulating layer over a second IC device; forming a 3D, bonded IC device by aligning and bonding the first insulating layer to the second insulating layer so as to define a bonding interface therebetween, defining a first set of vias within the 3D bonded IC device, the first set of vias landing on conductive pads located within the first IC device, and defining a second set of vias within the 3D bonded IC device, the second set of vias landing on conductive pads located within the second device, such that the second set of vias passes through the bonding interface; and filling the first and second sets of vias with a conductive material. | 10-21-2010 |
| 20100283093 | Structure and Method to Form EDRAM on SOI Substrate - A memory device is provided that in one embodiment includes a trench capacitor located in a semiconductor substrate including an outer electrode provided by the semiconductor substrate, an inner electrode provided by a conductive fill material, and a node dielectric layer located between the outer electrode and the inner electrode; and a semiconductor device positioned centrally over the trench capacitor. The semiconductor device includes a source region, a drain region, and a gate structure, in which the semiconductor device is formed on a semiconductor layer that is separated from the semiconductor substrate by a dielectric layer. A first contact is present extending from an upper surface of the semiconductor layer into electrical contact with the semiconductor substrate, and a second contact from the drain region of the semiconductor device in electrical contact to the conductive material within the at least one trench. | 11-11-2010 |
| 20100314711 | 3D INTEGRATED CIRCUIT DEVICE HAVING LOWER-COST ACTIVE CIRCUITRY LAYERS STACKED BEFORE HIGHER-COST ACTIVE CIRCUITRY LAYER - A method is provided for fabricating a 3D integrated circuit structure. According to the method, a first active circuitry layer wafer that includes active circuitry is provided, and a first portion of the first active circuitry layer wafer is removed such that a second portion of the first active circuitry layer wafer remains. Another wafer that includes active circuitry is provided, and the other wafer is bonded to the second portion of the first active circuitry layer wafer. The first active circuitry layer wafer is lower-cost than the other wafer. Also provided are a tangible computer readable medium encoded with a program for fabricating a 3D integrated circuit structure, and a 3D integrated circuit structure. | 12-16-2010 |
| 20110065214 | 3D MULTIPLE DIE STACKING - A process of forming three-dimensional (3D) die. A plurality of wafers are tested for die that pass (good die) or fail (bad die) predetermined test criteria. Two tested wafers are placed in proximity to each other. The wafers are aligned in such a manner so as to maximize the number of good die aligned between the two wafers. The two wafers are then bonded together and diced into individual stacks of bonded good die. | 03-17-2011 |
| 20110101496 | FOUR-TERMINAL ANTIFUSE STRUCTURE HAVING INTEGRATED HEATING ELEMENTS FOR A PROGRAMMABLE CIRCUIT - The present invention provides antifuse structures having an integrated heating element and methods of programming the same, the antifuse structures comprising first and second conductors and a dielectric layer formed between the conductors, where one or both of the conductors functions as both a conventional antifuse conductor and as a heating element for directly heating the antifuse dielectric layer during programming. | 05-05-2011 |
