Patent application number | Description | Published |
20090014878 | STRUCTURE AND METHOD OF FORMING ELECTRODEPOSITED CONTACTS - A contact metallurgy structure comprising a patterned dielectric layer having cavities on a substrate; a silicide or germanide layer such as of cobalt and/or nickel located at the bottom of cavities; a contact layer comprising Ti or Ti/TiN located on top of the dielectric layer and inside the cavities and making contact to the silicide or germanide layer on the bottom; a diffusion barrier layer located on top of the contact layer and inside the cavities; optionally a seed layer for plating located on top of the barrier layer; a metal fill layer in vias is provided along with a method of fabrication. The metal fill layer is electrodeposited with at least one member selected from the group consisting of copper, rhodium, ruthenium, iridium, molybdenum, gold, silver, nickel, cobalt, silver, gold, cadmium and zinc and alloys thereof. When the metal fill layer is rhodium, ruthenium, or iridium, an effective diffusion barrier layer is not required between the fill metal and the dielectric. When the barrier layer is platable, such as ruthenium, rhodium, platinum, or iridium, the seed layer is not required. | 01-15-2009 |
20100055442 | METHOD OF PE-ALD OF SiNxCy AND INTEGRATION OF LINER MATERIALS ON POROUS LOW K SUBSTRATES - A method of depositing a SiN | 03-04-2010 |
20110084393 | METHOD OF FORMING ELECTRODEPOSITED CONTACTS - A contact metallurgy structure comprising a patterned dielectric layer having vias on a substrate; a silicide layer of cobalt and/or nickel located at the bottom of vias; a contact layer comprising Ti located in vias on top of the silicide layer; a diffusion layer located in vias and on top of the contact layer; a metal fill layer in vias is provided along with a method of fabrication. The metal fill layer comprises at least one member selected from the group consisting of copper, ruthenium, rhodium platinum, palladium, iridium, rhenium, tungsten, gold, silver and osmium and alloys thereof. When the metal fill layer comprises rhodium, the diffusion layer is not required. Optionally a seed layer for the metal fill layer can be employed. | 04-14-2011 |
20110241213 | Silicide Contact Formation - A method for forming a silicide contact includes depositing a metal layer on silicon such that the metal layer intermixes with the silicon to form an intermixed region on the silicon; removing an unintermixed portion of the metal layer from the intermixed region; and annealing the intermixed region to form a silicide contact on the silicon. A semiconductor device comprising a silicide contact located over a silicon layer of the semiconductor device, the silicide contact comprising nickel (Ni) and silicon (Si) and having Ni amount equivalent to a thickness of about 21 angstroms or less. | 10-06-2011 |
20110308949 | NANO-FLUIDIC FIELD EFFECTIVE DEVICE TO CONTROL DNA TRANSPORT THROUGH THE SAME - The present invention provides a nano-fluidic field effective device. The device includes a channel having a first side and a second side, a first set of electrodes adjacent to the first side, a second set of electrodes adjacent to the second side, a control unit for applying electric potentials to the electrodes and a fluid within the channel containing a charge molecule. The first set of electrodes is disposed such that application of electric potentials produces a spatially varying electric field that confines a charged molecule within a predetermined area of said channel. The second set of electrodes is disposed such that application of electric potentials relative to the electric potentials applied to the first set of electrodes creates an electric field that confines the charged molecule to an area away from the second side of the channel. | 12-22-2011 |
20120132886 | NANOFLUDIC FIELD EFFECT TRANSISTOR BASED ON SURFACE CHARGE MODULATED NANOCHANNEL - A field effect transistor device includes: a reservoir bifurcated by a membrane of three layers: two electrically insulating layers; and an electrically conductive gate between the two insulating layers. The gate has a surface charge polarity different from at least one of the insulating layers. A nanochannel runs through the membrane, connecting both parts of the reservoir. The device further includes: an ionic solution filling the reservoir and the nanochannel; a drain electrode; a source electrode; and voltages applied to the electrodes (a voltage between the source and drain electrodes and a voltage on the gate) for turning on an ionic current through the ionic channel wherein the voltage on the gate gates the transportation of ions through the ionic channel. | 05-31-2012 |
20120301706 | METHOD OF PE-ALD OF SiNxCy AND INTEGRATION OF LINER MATERIALS ON POROUS LOW K SUBSTRATES - A method of depositing a SiN | 11-29-2012 |
20130009668 | 4-TERMINAL PIEZOELECTRONIC TRANSISTOR (PET) - A 4-terminal piezoelectronic transistor (PET) which includes a piezoelectric (PE) material disposed between first and second electrodes; an insulator material disposed on the second electrode; a third electrode disposed on the insulator material and a piezoresistive (PR) material disposed between the third electrode and a fourth electrode. An applied voltage across the first and second electrodes causing a pressure from the PE material to be applied to the PR material through the insulator material, the electrical resistance of the PR material being dependent upon the pressure applied by the PE material. The first and second electrodes are electrically isolated from the third and fourth electrodes. Also disclosed are logic devices fabricated from 4-terminal PETs and a method of fabricating a 4-terminal PET. | 01-10-2013 |
20150068902 | NANO-FLUIDIC FIELD EFFECTIVE DEVICE TO CONTROL DNA TRANSPORT THROUGH THE SAME - The present invention provides a nano-fluidic field effective device. The device includes a channel having a first side and a second side, a first set of electrodes adjacent to the first side, a second set of electrodes adjacent to the second side, a control unit for applying electric potentials to the electrodes and a fluid within the channel containing a charge molecule. The first set of electrodes is disposed such that application of electric potentials produces a spatially varying electric field that confines a charged molecule within a predetermined area of said channel. The second set of electrodes is disposed such that application of electric potentials relative to the electric potentials applied to the first set of electrodes creates an electric field that confines the charged molecule to an area away from the second side of the channel. | 03-12-2015 |