| Patent application number | Description | Published |
|---|
| 20080201681 | COMPUTER PROGRAM PRODUCTS FOR DETERMINING STOPPING POWERS OF DESIGN STRUCTURES WITH RESPECT TO A TRAVELING PARTICLE - A computer program product, comprising a computer usable medium having a computer readable program code embodied therein, said computer readable program code including an algorithm adapted to implement a method including the following steps. First, design information of the design structure is provided including a back-end-of-line layer of the integrated circuit which includes N interconnect layers, N being a positive integer. Next, each interconnect layer of the N interconnect layers is divided into multiple pixels. Next, a first path of a traveling particle in a first interconnect layer of the N interconnect layers is determined. Next, M path pixels of the multiple pixels of the first interconnect layer on the first path of the traveling particle are identified, M being a positive integer. Next, a first loss energy lost by the traveling particle due to its completely passing through a first pixel of the M path pixels is determined. | 08-21-2008 |
| 20080211100 | METHOD AND STRUCTURE FOR REDUCING CONTACT RESISTANCE BETWEEN SILICIDE CONTACT AND OVERLYING METALLIZATION - A semiconductor structure in which the contact resistance in the contact opening is reduced as well as a method of forming the same are provided. This is achieved in the present invention by replacing conventional contact metallurgy, such as tungsten, or a metal silicide, such as Ni silicide or Cu silicide, with a metal germanide-containing contact material. The term “metal germanide-containing” is used in the present application to denote a pure metal germanide (i.e., MGe alloy) or a metal germanide that includes Si (i.e., MSiGe alloy). | 09-04-2008 |
| 20080225573 | STATIC RANDOM ACCESS MEMORY CELL WITH IMPROVED STABILITY - A memory cell comprises a wordline, a first digital inverter with a first input and a first output, and a second digital inverter with a second input and a second output. Moreover, the memory cell further comprises a first feedback connection connecting the first output to the second input, and a second feedback connection connecting the second output to the first input. The first feedback connection comprises a first resistive element and the second feedback connection comprises a second resistive element. What is more, each digital inverter has an associated capacitance. The memory cell is configured such that reading the memory cell includes applying a read voltage pulse to the wordline. In addition, the first and second resistive elements are configured such that the first and second feedback connections have resistance-capacitance induced delays longer than the applied read voltage pulse. | 09-18-2008 |
| 20080299720 | STABILIZATION OF Ni MONOSILICIDE THIN FILMS IN CMOS DEVICES USING IMPLANTATION OF IONS BEFORE SILICIDATION - A method for forming a stabilized metal silicide film, e.g., contact (source/drain or gate), that does not substantially agglomerate during subsequent thermal treatments, is provided. In the present invention, ions that are capable of attaching to defects within the Si-containing layer are implanted into the Si-containing layer prior to formation of metal silicide. The implanted ions stabilize the film, because the implants were found to substantially prevent agglomeration or at least delay agglomeration to much higher temperatures than in cases in which no implants were used. | 12-04-2008 |
| 20080308747 | RADIATION DETECTION SCHEMES, APPARATUS AND METHODS OF TRANSMITTING RADIATION DETECTION INFORMATION TO A NETWORK - Personal radiation detection devices, methods of obtaining radiation exposure data, and networks of personal radiation devices. The detection devices may include passive devices and active devices. The passive detection devices may have the same form factor as credit cards or be included in common types of credit card form factor sized cards. The active devices may be incorporated into common and widely distributed host devices. | 12-18-2008 |
| 20080311745 | High Temperature Processing Compatible Metal Gate Electrode For pFETS and Methods For Fabrication - A method for fabricating a CMOS gate electrode by using Re, Rh, Pt, Ir or Ru metal and a CMOS structure that contains such gate electrodes are described. The work functions of these metals make them compatible with current pFET requirements. For instance, the metal can withstand the high hydrogen pressures necessary to produce properly passivated interfaces without undergoing chemical changes. The thermal stability of the metal on dielectric layers such as SiO | 12-18-2008 |
| 20080318365 | FORMATION OF ALPHA PARTICLE SHIELDS IN CHIP PACKAGING - A structure fabrication method. First, an integrated circuit including N chip electric pads is provided electrically connected to a plurality of devices on the integrated circuit. Then, an interposing shield having a top side and a bottom side and having N electric conductors in the interposing shield is provided being exposed to a surrounding ambient at the top side but not at the bottom side. Next, the integrated circuit is bonded to the top side of the interposing shield such that the N chip electric pads are in electrical contact with the N electric conductors. Next, the bottom side of the interposing shield is polished so as to expose the N electric conductors to the surrounding ambient at the bottom side of the interposing shield. Then, N solder bumps are formed on the polished bottom side of the interposing shield and in electrical contact with the N electric conductors. | 12-25-2008 |
| 20090039515 | IONIZING RADIATION BLOCKING IN IC CHIP TO REDUCE SOFT ERRORS - Methods of blocking ionizing radiation to reduce soft errors and resulting IC chips are disclosed. One embodiment includes forming a front end of line (FEOL) for an integrated circuit (IC) chip; and forming at least one back end of line (BEOL) dielectric layer including ionizing radiation blocking material therein. Another embodiment includes forming a front end of line (FEOL) for an integrated circuit (IC) chip; and forming an ionizing radiation blocking layer positioned in a back end of line (BEOL) of the IC chip. The ionizing radiation blocking material or layer absorbs ionizing radiation and reduces soft errors within the IC chip. | 02-12-2009 |
| 20090059657 | CMOS STORAGE DEVICES CONFIGURABLE IN HIGH PERFORMANCE MODE OR RADIATION TOLERANT MODE - A radiation tolerant circuit, structure of the circuit and method of autonomic radiation event device protection. The circuit includes a charge storage node connected to a resistor, the resistor comprising a material having an amorphous state and a crystalline state, the amorphous state having a higher resistance than the crystalline state, the material reversibly convertible between the amorphous state and the crystalline state by application of heat; an optional resistive heating element proximate to the resistor; and means for writing data to the charge storage node and means for reading data from the charge storage node. | 03-05-2009 |
| 20090065955 | METHOD AND STRUCTURES FOR ACCELERATED SOFT-ERROR TESTING - An integrated circuit, method of forming the integrated circuit and a method of testing the integrated circuit for soft-error fails. The integrated circuit includes: a silicon substrate; a dielectric layer formed over the substrate; electrically conductive wires formed in the dielectric layer, the wires interconnecting semiconductor devices formed in the substrate into circuits; and an alpha particle emitting region in the integrated circuit chip proximate to one or more of the semiconductor devices. The method includes exposing the integrated circuit to an artificial flux of thermal neutrons to cause fission of atoms in the alpha particle emitting region into alpha particles and other atoms. | 03-12-2009 |
| 20090108212 | RADIATION DETECTION SCHEMES, APPARATUS AND METHODS OF TRANSMITTING RADIATION DETECTION INFORMATION TO A NETWORK - Personal radiation detection devices, methods of obtaining radiation exposure data, and networks of personal radiation devices. The detection devices may include passive devices and active devices. The passive detection devices may have the same form factor as credit cards or be included in common types of credit card form factor sized cards. | 04-30-2009 |
| 20090206484 | MICROSTRUCTURE MODIFICATION IN COPPER INTERCONNECT STRUCTURE - Cobalt is added to a copper seed layer, a copper plating layer, or a copper capping layer in order to modify the microstructure of copper lines and vias. The cobalt can be in the form of a copper-cobalt alloy or as a very thin cobalt layer. The grain boundaries configured in bamboo microstructure in the inventive metal interconnect structure shut down copper grain boundary diffusion. The composition of the metal interconnect structure after grain growth contains from about 1 ppm to about 10% of cobalt in atomic concentration. Grain boundaries extend from a top surface of a copper-cobalt alloy line to a bottom surface of the copper-cobalt alloy line, and are separated from any other grain boundary by a distance greater than a width of the copper-cobalt alloy line. | 08-20-2009 |
| 20090236699 | DISCREET PLACEMENT OF RADIATION SOURCES ON INTEGRATED CIRCUIT DEVICES - An integrated circuit and methods of forming and using the integrated circuit. The circuit includes: a radiation-emitting layer over a selected region of a top surface of an integrated circuit chip, the radiation emitting layer comprising a first polymer or resin and a first radioactive material, the region smaller than a whole of the top surface of the integrated circuit chip, the region including a circuit that is liable to temporary failure when struck by radiation generated by the first radioactive material. | 09-24-2009 |
| 20090315182 | SILICIDE INTERCONNECT STRUCTURE - A method for forming an interconnect structure includes forming a dielectric layer above a first layer having a conductive region defined therein. An opening is defined in the dielectric layer to expose at least a portion of the conductive region. A metal silicide is formed in the opening to define the interconnect structure. A semiconductor device includes a first layer having a conductive region defined therein, a dielectric layer formed above the first layer, and a metal silicide interconnect structure extending through the dielectric layer to communicate with the conductive region. | 12-24-2009 |
| 20100323517 | MICROSTRUCTURE MODIFICATION IN COPPER INTERCONNECT STRUCTURE - Cobalt is added to a copper seed layer, a copper plating layer, or a copper capping layer in order to modify the microstructure of copper lines and vias. The cobalt can be in the form of a copper-cobalt alloy or as a very thin cobalt layer. The grain boundaries configured in bamboo microstructure in the inventive metal interconnect structure shut down copper grain boundary diffusion. The composition of the metal interconnect structure after grain growth contains from about 1 ppm to about 10% of cobalt in atomic concentration. Grain boundaries extend from a top surface of a copper-cobalt alloy line to a bottom surface of the copper-cobalt alloy line, and are separated from any other grain boundary by a distance greater than a width of the copper-cobalt alloy line. | 12-23-2010 |
| 20110088008 | METHOD FOR CONVERSION OF COMMERCIAL MICROPROCESSOR TO RADIATION-HARDENED PROCESSOR AND RESULTING PROCESSOR - A method is provided to convert commercial microprocessors to radiation-hardened processors and, more particularly, a method is provided to modify a commercial microprocessor for radiation hardened applications with minimal changes to the technology, design, device, and process base so as to facilitate a rapid transition for such radiation hardened applications. The method is implemented in a computing infrastructure and includes evaluating a probability that one or more components of an existing commercial design will be affected by a single event upset (SEU). The method further includes replacing the one or more components with a component immune to the SEU to create a final device. | 04-14-2011 |
