Patent application number | Description | Published |
20120091550 | SPECTROSCOPY AND SPECTRAL IMAGING METHODS AND APPARATUS - The invention pertains to a new type of standing wave filter in which the detector is located within the cavity, rather than outside the cavity and methods of manufacturing such a filter. | 04-19-2012 |
20120200852 | SPECTROSCOPY AND SPECTRAL IMAGING METHODS AND APPARATUS - The invention pertains to a new type of spectroscope comprising an array of Fabry-Perot cells having no moving parts and that can be fabricated inexpensively using semiconductor fabrication techniques. | 08-09-2012 |
20130122670 | PROCESS TO REMOVE Ni AND Pt RESIDUES FOR NiPtSi APPLICATIONS USING CHLORINE GAS - The invention discloses a method for cleaning residues from a semiconductor substrate during a nickel platinum silicidation process. Post silicidation residues of nickel and platinum may not be removed adequately just by an aqua regia solution (comprising a mixture of nitric acid and hydrochloric acid). Therefore, embodiments of the invention provide a multi-step residue cleaning, comprising exposing the substrate to an aqua regia solution, followed by an exposure to a chlorine gas or a solution comprising dissolved chlorine gas, which may further react with remaining platinum residues, rendering it more soluble in aqueous solution and thereby dissolving it from the surface of the substrate. | 05-16-2013 |
20130267091 | Process to remove Ni and Pt residues for NiPtSi application using Chlorine gas - The invention discloses a method for cleaning residues from a semiconductor substrate during a nickel platinum silicidation process. Post silicidation residues of nickel and platinum may not be removed adequately just by an aqua regia solution (comprising a mixture of nitric acid and hydrochloric acid). Therefore, embodiments of the invention provide a multi-step residue cleaning, comprising exposing the substrate to an aqua regia solution, followed by an exposure to a chlorine gas or a solution comprising dissolved chlorine gas, which may further react with remaining platinum residues, rendering it more soluble in aqueous solution and thereby dissolving it from the surface of the substrate. | 10-10-2013 |
20130316472 | HIGH PRODUCTIVITY COMBINATORIAL OXIDE TERRACING AND PVD/ALD METAL DEPOSITION COMBINED WITH LITHOGRAPHY FOR GATE WORK FUNCTION EXTRACTION - Metal gate high-k capacitor structures with lithography patterning are used to extract gate work function using a combinatorial workflow. Oxide terracing, together with high productivity combinatorial process flow for metal deposition can provide optimum high-k gate dielectric and metal gate solutions for high performance logic transistors. The high productivity combinatorial technique can provide an evaluation of effective work function for given high-k dielectric metal gate stacks for PMOS and NMOS transistors, which is critical in identifying and selecting the right materials. | 11-28-2013 |
20140055152 | CIRCULAR TRANSMISSION LINE METHODS COMPATIBLE WITH COMBINATORIAL PROCESSING OF SEMICONDUCTORS - Methods and structures are described for determining contact resistivities and Schottky barrier heights for conductors deposited on semiconductor wafers that can be combined with combinatorial processing, allowing thereby numerous processing conditions and materials to be tested concurrently. Methods for using multi-ring as well as single-ring CTLM structures to cancel parasitic resistance are also described, as well as structures and processes for inline monitoring of properties. | 02-27-2014 |
20150061027 | METHODS OF FORMING GATE STRUCTURES FOR TRANSISTOR DEVICES FOR CMOS APPLICATIONS AND THE RESULTING PRODUCTS - One method for forming replacement gate structures for NMOS and PMOS transistors includes performing an etching process to remove a sacrificial gate structure for the NMOS and PMOS transistors to thereby define NMOS and PMOS gate cavities, depositing a gate insulation layer in the gate cavities, depositing a first metal layer on the gate insulation layer in the gate cavities, performing at least one process operation to form (1) an NMOS metal silicide material above the first metal layer within the NMOS gate cavity, the NMOS metal silicide material having a first amount of atomic silicon, and (2) a PMOS metal silicide material above the first metal layer within the PMOS gate cavity, the PMOS metal silicide material having a second amount of atomic silicon, and wherein the first and second amounts of atomic silicon are different, and forming gate cap layers within the NMOS and PMOS gate cavities. | 03-05-2015 |
20150311206 | METHODS OF FORMING GATE STRUCTURES FOR TRANSISTOR DEVICES FOR CMOS APPLICATIONS AND THE RESULTING PRODUCTS - An integrated circuit product includes an NMOS transistor having a gate structure that includes an NMOS gate insulation layer, a first NMOS metal layer positioned on the NMOS gate insulation layer, an NMOS metal silicide material positioned above the first NMOS metal layer, and a layer of a second metal material positioned above and in contact with the NMOS gate insulation layer, the first NMOS metal layer, and the NMOS metal silicide layer. The PMOS transistor has a gate structure that includes a PMOS gate insulation layer, a first PMOS metal layer positioned on the PMOS gate insulation layer, a PMOS metal silicide material positioned above the first PMOS metal layer, and a layer of the second metal material positioned above and in contact with the PMOS gate insulation layer, the first PMOS metal layer, and the PMOS metal silicide layer. | 10-29-2015 |