Product Patents (Class 423/447.2)
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Patent number: 10233566Abstract: Systems and methods for synthesizing continuous single crystal graphene are provided. A catalytic substrate is drawn through a chemical vapor deposition chamber in a first lengthwise direction while flowing a hydrogen gas through the chemical vapor deposition chamber in the same lengthwise direction. A hydrocarbon precursor gas is supplied directly above a surface of the catalytic substrate. A high concentration gradient of the hydrocarbon precursor at the crystal growth front is generated to promote the growth of a continuous single crystal graphene film while suppressing the growth of seed domains ahead of the crystal growth front.Type: GrantFiled: December 29, 2016Date of Patent: March 19, 2019Assignee: UT-Battelle, LLCInventors: Frederick Alyious List, III, Yijing Y. Stehle, Ivan V. Vlassiouk, Sergei N. Smirnov
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Patent number: 10189713Abstract: Provided is a method for efficiently producing a carbon nanotube dispersion liquid in which less-damaged carbon nanotubes are highly dispersed. The method for producing a carbon nanotube dispersion liquid includes: (A) obtaining a carbon nanotube dispersion liquid by applying a shear force to a coarse dispersion liquid that includes carbon nanotubes having a specific surface area of 600 m2/g or more to whereby disperse the carbon nanotubes, wherein the step (A) includes at least one of applying a back pressure to the carbon nanotube dispersion liquid and cooling the carbon nanotube dispersion liquid.Type: GrantFiled: July 23, 2014Date of Patent: January 29, 2019Assignee: ZEON CORPORATIONInventors: Mitsugu Uejima, Masahiro Shigeta
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Patent number: 10170752Abstract: A method for producing an amorphous carbon particle includes the steps of: obtaining a first crosslinked product by admixing mesophase particles with an amorphous carbon precursor and thereafter subjecting the mixture to a crosslinking treatment, or obtaining a second crosslinked product by crosslinking the amorphous carbon precursor and thereafter admixing the mesophase particles with the crosslinked precursor; and subjecting the first or second crosslinked product to an infusibilization treatment and thereafter firing the product to produce amorphous carbon particles including the mesophase particles within the particles.Type: GrantFiled: June 12, 2013Date of Patent: January 1, 2019Assignee: JFE CHEMICAL CORPORATIONInventors: Makiko Ijiri, Ryuta Haga, Tetsuo Shiode, Katsuhiro Nagayama
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Patent number: 10151051Abstract: The invention is directed to carbon fibers having high tensile strength and modulus of elasticity. The invention also provides a method and apparatus for making the carbon fibers. The method comprises advancing a precursor fiber through an oxidation oven wherein the fiber is subjected to controlled stretching in an oxidizing atmosphere in which tension loads are distributed amongst a plurality of passes through the oxidation oven, which permits higher cumulative stretches to be achieved. The method also includes subjecting the fiber to controlled stretching in two or more of the passes that is sufficient to cause the fiber to undergo one or more transitions in each of the two or more passes. The invention is also directed to an oxidation oven having a plurality of cooperating drive rolls in series that can be driven independently of each other so that the amount of stretch applied to the oven in each of the plurality of passes can be independently controlled.Type: GrantFiled: February 19, 2018Date of Patent: December 11, 2018Assignee: Hexcel CorporationInventor: Carlos A. León y León
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Patent number: 10138347Abstract: Provided is a method for efficiently producing a carbon nanotube (CNT) dispersion liquid of highly dispersed CNTs while also suppressing damage to the CNTs. The method for producing a carbon nanotube dispersion liquid includes a dispersing step that includes at least one cycle of dispersing treatment in which pressure is applied to a coarse dispersion liquid containing carbon nanotubes and a dispersion medium, the coarse dispersion liquid is fed under pressure, and shear force is applied to the coarse dispersion liquid such as to disperse the carbon nanotubes. A plurality of repetitions of the dispersing step are performed while altering the pressure that is applied to the coarse dispersion liquid. In at least one instance, the pressure applied to the coarse dispersion liquid is altered by at least 10 MPa between consecutive repetitions of the dispersing step.Type: GrantFiled: May 18, 2015Date of Patent: November 27, 2018Assignee: ZEON CORPORATIONInventors: Masahiro Shigeta, Mitsugu Uejima
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Patent number: 10138120Abstract: Nanostructured assemblies are manufactured by condensing an evaporated wetting agent onto a nanostructure array formed from a plurality of generally aligned carbon nanotubes or other nanostructures. The condensed wetting agent draws the individual nanostructures together to form various geometries of nanostructured assemblies based on various parameters including process variables and the starting shape and dimensional features of the nanostructure array. Various simple and complex geometries can be achieved in this manner, including geometries that are curved, bent, or twisted. Adjacent nanostructure arrays of the same or different starting geometries can be shaped into compound or interrelating structures. Additional process steps such as plasma etching, coating and others can be used to control the shaping and structural attributes of the nanostructured assemblies. A method of making a molded replica of a shaped nanostructure array is also disclosed.Type: GrantFiled: March 31, 2010Date of Patent: November 27, 2018Assignee: THE REGENTS OF THE UNIVERSITY OF MICHIGANInventors: Anastasios John Hart, Sameh Tawfick, Michael DeVolder, Davor Copic
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Patent number: 10099460Abstract: A method for producing a preform for manufacture of a fiber-reinforced plastic molding. The method includes: fixing a resin-equipped film rolled out from a roll state including a release film and a fixing resin and containing a partially-cured thermosetting resin, to a surface of the dry fiber fabric rolled out from a roll with the fixing resin interposed therebetween, thereby obtaining a first dry fiber fabric; separately fixing the resin-equipped film to a surface of the dry fiber fabric rolled out from a roll with the fixing resin interposed therebetween, and detaching the release film, thereby obtaining one or more second dry fiber fabrics; and laminating the second dry fiber fabrics on a surface of the first dry fiber fabric with the fixing resin of the second dry fiber fabrics interposed therebetween.Type: GrantFiled: September 6, 2012Date of Patent: October 16, 2018Assignee: Mitsubishi Electric CorporationInventors: Sohei Samejima, Hajime Takeya, Michihito Matsumoto, Hiroki Kobayashi, Kazuki Kubo, Yuhei Awano, Takahiro Mabuchi
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Patent number: 10099950Abstract: The invention relates to bio-electrochemical systems for treating wastewater, and sour gas produced by anaerobic digestion of organic material. The invention further relates to novel anode/cathode pairing schemes, and electric and hydraulic architectures for use in bio-electrochemical systems.Type: GrantFiled: April 14, 2011Date of Patent: October 16, 2018Assignee: CAMBRIAN INNOVATION LLCInventors: Matthew Silver, Justin Buck, Patrick Kiely, Juan J. Guzman
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Patent number: 10023979Abstract: A bundle of carbon fibers has a value A obtained from a nonlinear approximation formula of a stress ?-strain ? curve in a tensile strength test of resin-impregnated strands and an orientation parameter ? (%) of crystallites in a wide-angle x-ray diffraction measurement which satisfy a predetermined relational expression, and has tensile strength with a predetermined value or more, and tensile modulus within a predetermined range and a product E×d/W of a ratio d/W of a single-fiber diameter d to a loop width W just before loop fracture evaluated by a single-fiber loop test and a tensile modulus E of the strands has a predetermined value or more, or apparent single-fiber stress has a predetermined value or more when the number of fiber breaks by a single-fiber fragmentation method for a single-fiber composite is 0.30 breaks/mm and when the number of the fiber breaks by the single-fiber fragmentation method for the single-fiber composite is 0.Type: GrantFiled: October 23, 2015Date of Patent: July 17, 2018Assignee: Toray Industries, Inc.Inventors: Naohiro Matsumoto, Jun Watanabe, Haruki Okuda, Fumihiko Tanaka
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Patent number: 9988313Abstract: We provide a method for the in situ development of graphene containing silicon carbide (SiC) matrix ceramic composites, and more particularly to the in situ graphene growth within the bulk ceramic through a single-step approach during SiC ceramics densification using an electric current activated/assisted sintering (ECAS) technique. This approach allows processing dense, robust, highly electrical conducting and well dispersed nanocomposites having a percolated graphene network, eliminating the handling of potentially hazardous nanostructures. Graphene/SiC components could be used in technological applications under strong demanding conditions where good electrical, thermal, mechanical and/or tribological properties are required, such as micro and nanoelectromechanical systems (MEMS and NEMS), sensors, actuators, heat exchangers, breaks, components for engines, armors, cutting tools, microturbines or microrotors.Type: GrantFiled: September 19, 2013Date of Patent: June 5, 2018Assignee: The Penn State Research FoundationInventors: Pilar Miranzo, Carmen Ocal, Maria Isabel Osendi, Manuel Belmonte, Cristina Ramirez, Benito Roman-Manso, Humberto R. Gutierrez, Mauricio Terrones
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Patent number: 9988412Abstract: The present invention relates to fractions of high purity lignin which are thermally stable, and to methods of producing said fractions from lignocellulosic material.Type: GrantFiled: May 12, 2017Date of Patent: June 5, 2018Assignee: VIRDIA, INC.Inventors: Robert Jansen, James Alan Lawson, Noa Lapidot, Bassem Hallac, Perry Rotem
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Patent number: 9938643Abstract: The invention is directed to carbon fibers having high tensile strength and modulus of elasticity. The invention also provides a method and apparatus for making the carbon fibers. The method comprises advancing a precursor fiber through an oxidation oven wherein the fiber is subjected to controlled stretching in an oxidizing atmosphere in which tension loads are distributed amongst a plurality of passes through the oxidation oven, which permits higher cumulative stretches to be achieved. The method also includes subjecting the fiber to controlled stretching in two or more of the passes that is sufficient to cause the fiber to undergo one or more transitions in each of the two or more passes. The invention is also directed to an oxidation oven having a plurality of cooperating drive rolls in series that can be driven independently of each other so that the amount of stretch applied to the oven in each of the plurality of passes can be independently controlled.Type: GrantFiled: May 5, 2017Date of Patent: April 10, 2018Assignee: Hexel CorporationInventor: Carlos A. León y León
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Patent number: 9917308Abstract: The present invention provides a method for producing metal-supported carbon, which includes supporting metal microparticles on the surface of carbon black, by a liquid-phase reduction method, in a thin film fluid formed between processing surfaces arranged to be opposite to each other so as to be able to approach to and separate from each other, at least one of which rotates relative to the other, as well as a method for producing crystals comprising fullerene molecules and fullerene nanowhisker/nanofiber nanotubes, which includes uniformly stirring and mixing a solution containing a first solvent having fullerene dissolved therein, and a second solvent in which fullerene is less soluble than in the first solvent, in a thin film fluid formed between processing surfaces arranged to be opposite to each other so as to be able to approach to and separate from each other, at least one of which rotates relative to the other.Type: GrantFiled: January 29, 2015Date of Patent: March 13, 2018Assignee: M. TECHNIQUE CO., LTD.Inventor: Masakazu Enomura
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Patent number: 9847181Abstract: The present invention provides: a film that comprises single-layer carbon nanotubes having shapes which enable the characteristics thereof to be sufficiently exhibited; and a process for producing the film. The film, which comprises single-layer carbon nanotubes, has portions where single-layer carbon nanotubes are densely present and portions where single-layer carbon nanotubes are sparsely present, the dense portions forming a pseudo-honeycomb structure in a surface of the film.Type: GrantFiled: March 3, 2014Date of Patent: December 19, 2017Assignee: THE UNIVERSITY OF TOKYOInventors: Shigeo Maruyama, Shohei Chiashi, Kehang Cui
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Patent number: 9765448Abstract: A flame resistant polymer is obtained by reacting polyacrylonitrile with amine and nitro compounds, the polyacrylonitrile being polymerized by aqueous suspension polymerization using a redox initiator and containing an S component at an amount of 3,000 ?g/g or less. A PAN-based polymer in which both yarn producing properties and flame resistance are improved can be realized.Type: GrantFiled: July 11, 2014Date of Patent: September 19, 2017Assignee: The University of TokyoInventors: Tetsunori Higuchi, Mami Sakaguchi
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Patent number: 9745471Abstract: A prepreg 10 comprises: a reinforcing fiber layer 3 including reinforcing fibers 1 and a resin composition 2 with which the space between fibers of the reinforcing fibers 1 is impregnated and which contains (A) a benzoxazine resin, (B) an epoxy resin, and (C) a curing agent having 2 or more phenolic hydroxy groups in a molecule; and a surface layer 6a or 6b provided on at least one surface of the reinforcing fiber layer 3 and containing (A) a benzoxazine resin, (B) an epoxy resin, (C) a curing agent having 2 or more phenolic hydroxy groups in a molecule, and (D) polyamide resin particles 4 having an average particle size of 5 to 50 ?m, wherein the polyamide resin particles 4 include a particle made of a polyamide 11.Type: GrantFiled: March 24, 2014Date of Patent: August 29, 2017Assignees: JX NIPPON OIL & ENERGY CORPORATION, FUJI JUKOGYO KABUSHIKI KAISHAInventors: Yoshihiro Fukuda, Takayuki Matsumoto, Masaki Minami, Naoyuki Sekine, Masanori Nakajima
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Patent number: 9711296Abstract: An energy storage device includes a first electrode and a second electrode comprising nanostructures. The nanostructures comprise defects that increase charge storage capabilities of the energy storage device. A method of fabricating an energy storage device includes producing a nanomaterial comprising nanostructures and generating defects in the nanomaterial using an electrophilic or nucleophilic additive for increasing charge storage capability of the nanomaterial.Type: GrantFiled: November 2, 2011Date of Patent: July 18, 2017Assignee: THE REGENTS OF THE UNIVERSITY OF CALIFORNIAInventors: Prabhakar R. Bandaru, Mark Hoefer
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Patent number: 9688538Abstract: An improved graft polymerization method from general graphitic structures with organic based monomers through the mechanism of Reversible Addition-Fragmentation Chain Transfer (RAFT) polymerization was developed. Organic hybrid nanomaterials comprising graphitic structures are covalently bonded via chemically reactive groups on the outer walls of the structure. Methods for forming the covalently bonded structures to many organic based monomers and/or polymers may occur through RAFT polymerization utilizing dithioester as a chain transfer agent. The method may also comprise nanocomposite formation of such organic hybrid nanomaterials with common plastic(s) to form graphitic nanocomposite reinforced plastic articles.Type: GrantFiled: February 5, 2015Date of Patent: June 27, 2017Assignee: UNIVERSITY OF HOUSTON SYSTEMInventors: Seamus Curran, Kang-Shyang Liao, Alexander Wang
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Patent number: 9677195Abstract: The invention is directed to carbon fibers having high tensile strength and modulus of elasticity. The invention also provides a method and apparatus for making the carbon fibers. The method comprises advancing a precursor fiber through an oxidation oven wherein the fiber is subjected to controlled stretching in an oxidizing atmosphere in which tension loads are distributed amongst a plurality of passes through the oxidation oven, which permits higher cumulative stretches to be achieved. The method also includes subjecting the fiber to controlled stretching in two or more of the passes that is sufficient to cause the fiber to undergo one or more transitions in each of the two or more passes. The invention is also directed to an oxidation oven having a plurality of cooperating drive rolls in series that can be driven independently of each other so that the amount of stretch applied to the oven in each of the plurality of passes can be independently controlled.Type: GrantFiled: May 2, 2016Date of Patent: June 13, 2017Assignee: Hexcel CorporationInventor: Carlos A. León y León
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Patent number: 9597677Abstract: The invention relates to a method allowing functionalization of carbon nano-objects and in particular carbon nanotubes and graphene nanosheets, a composition comprising nano-objects functionalized by this method, suspended in an organic solvent, as well as to the uses of this composition. Suitable applications include elaboration of composite materials and, in particular, of nano-composite materials, materials intended for photovoltaics, detection devices of the detector/sensor or biodetector/biosensor type, photocatalysis systems, targeted vectorization systems for compounds of therapeutic or diagnostic interest or further contrast agents for medical imaging.Type: GrantFiled: February 13, 2013Date of Patent: March 21, 2017Assignee: COMMISSARIAT ÁL'ÉNERGIE ATOMIQUE ET AUX ÉNERGIES ALTERNATIVESInventors: Stéphane Campidelli, Guillaume Clave
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Patent number: 9561066Abstract: The present application discloses devices that ablate human tissue. The device comprises a catheter with a shaft through which an ablative agent can travel, a liquid reservoir and a heating component, which may comprise a length of coiled tubing contained within a heating element, wherein activation of said heating element causes said coiled tubing to increase from a first temperature to a second temperature and wherein the increase causes a conversion of liquid within the coiled tubing to vapor, a reusable cord connecting the outlet of the reservoir to the inlet of the heating component, and a single use cord connecting a pressure-resistant inlet port of a vapor based ablation device to the outlet of the heating component.Type: GrantFiled: June 1, 2012Date of Patent: February 7, 2017Inventors: Virender K. Sharma, William Parks
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Patent number: 9540243Abstract: Systems and methods for the formation of nanostructures, including carbon-based nanostructures, are generally described. In certain embodiments, substrate configurations and associated methods are described.Type: GrantFiled: March 17, 2014Date of Patent: January 10, 2017Assignee: Massachusetts Institute of TechnologyInventors: Stephen A. Steiner, III, Brian L. Wardle, Richard Li
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Patent number: 9529129Abstract: The present invention in one aspect relates to a low-cost, nano-graphene based broadband optical limiter with limiting properties superior to current standards, carbon fullerenes (C60) solutions and carbon black suspensions. The broadband optical limiter includes a plurality of graphene nano-sheets, and a base material in which the plurality of graphene nano-sheets is distributed. The base material can be liquid or gel matrix.Type: GrantFiled: April 23, 2010Date of Patent: December 27, 2016Assignee: BOARD OF TRUSTEES OF THE UNIVERSITY OF ARKANSASInventors: Wei Zhao, Boshan Zhao
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Patent number: 9478364Abstract: Carbon-based electrodes such as for incorporation into ultracapacitors or other high power density energy storage devices, include activated carbon, carbon black, binder and at least one molecular sieve material. The molecular sieve component can adsorb and trap water, which can facilitate the use of the device at higher voltage, such as greater than 3V. The molecular sieve material may be incorporated into the carbon-based electrodes or formed as a layer over a carbon-based electrode surface.Type: GrantFiled: January 28, 2014Date of Patent: October 25, 2016Assignee: Corning IncorporatedInventors: Kishor Purushottam Gadkaree, Atul Kumar, Xiaorong Liu
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Patent number: 9412998Abstract: A novel hybrid lithium-ion anode material based on coaxially coated Si shells on vertically aligned carbon nanofiber (CNF) arrays. The unique cup-stacking graphitic microstructure makes the bare vertically aligned CNF array an effective Li+ intercalation medium. Highly reversible Li+ intercalation and extraction were observed at high power rates. More importantly, the highly conductive and mechanically stable CNF core optionally supports a coaxially coated amorphous Si shell which has much higher theoretical specific capacity by forming fully lithiated alloy. The broken graphitic edges at the CNF sidewall ensure good electrical connection with the Si shell during charge/discharge processes.Type: GrantFiled: December 21, 2012Date of Patent: August 9, 2016Inventors: Ronald A. Rojeski, Steven Klankowski, Jun Li
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Patent number: 9394178Abstract: A method for transfer of a two-dimensional material includes forming a spreading layer of a two-dimensional material on a substrate, the spreading layer having a monolayer. A stressor layer is formed on the spreading layer, and the stressor layer is configured to apply stress to a closest monolayer of the spreading layer. The closest monolayer is exfoliated by mechanically splitting the spreading layer wherein the closest monolayer remains on the stressor layer.Type: GrantFiled: August 3, 2015Date of Patent: July 19, 2016Assignee: INTERNATIONAL BUSINESS MACHINES CORPORATIONInventors: Stephen W. Bedell, Christos D. Dimitrakopoulos, Keith E. Fogel, James B. Hannon, Jeehwan Kim, Hongsik Park, Dirk Pfeiffer, Devendra K. Sadana
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Patent number: 9365728Abstract: In this invention, processes which can be used to achieve stable doped carbon nanotubes are disclosed. Preferred CNT structures and morphologies for achieving maximum doping effects are also described. Dopant formulations and methods for achieving doping of a broad distribution of tube types are also described.Type: GrantFiled: March 9, 2007Date of Patent: June 14, 2016Assignee: Battelle Memorial InstituteInventors: Amy M. Heintz, Steven Risser, Joel D. Elhard, Bryon P. Moore, Tao Liu, Bhima R. Vijayendran
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Patent number: 9340905Abstract: The invention is directed to carbon fibers having high tensile strength and modulus of elasticity. The invention also provides a method and apparatus for making the carbon fibers. The method comprises advancing a precursor fiber through an oxidation oven wherein the fiber is subjected to controlled stretching in an oxidizing atmosphere in which tension loads are distributed amongst a plurality of passes through the oxidation oven, which permits higher cumulative stretches to be achieved. The method also includes subjecting the fiber to controlled stretching in two or more of the passes that is sufficient to cause the fiber to undergo one or more transitions in each of the two or more passes. The invention is also directed to an oxidation oven having a plurality of cooperating drive rolls in series that can be driven independently of each other so that the amount of stretch applied to the oven in each of the plurality of passes can be independently controlled.Type: GrantFiled: July 13, 2015Date of Patent: May 17, 2016Assignee: Hexcel CorporationInventor: Carlos A. León y León
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Patent number: 9315679Abstract: Disclosed is a transparent conductive film containing a single-walled carbon nanotube and a fullerene.Type: GrantFiled: April 24, 2008Date of Patent: April 19, 2016Assignee: Kuraray Co., Ltd.Inventor: Takahiro Kitano
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Patent number: 9266909Abstract: This invention selectively synthesizes a cycloparaphenylene compound having 10, 11, or 13 benzene rings. The invention also synthesizes a cycloparaphenylene compound in which a functional group is introduced into a desired portion. By reacting specific raw materials using a specific reaction, a cyclic compound having 10, 11, or 13 bivalent aromatic hydrocarbon groups, bivalent heterocyclic groups, or derivative groups thereof can be selectively obtained as a pure substance.Type: GrantFiled: March 7, 2013Date of Patent: February 23, 2016Assignee: National University Corporation Nagoya UniversityInventors: Kenichiro Itami, Yasutomo Segawa, Haruka Omachi, Sanae Matsuura, Yusuke Nakanishi, Yuuki Ishii
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Patent number: 9260565Abstract: Disclosed herein are fiber reinforced thermoplastic composite with desired physical properties, such as high strength, high impact and high flow while maintaining the OSU heat release compliancy.Type: GrantFiled: July 10, 2012Date of Patent: February 16, 2016Assignee: SABIC Global Technologies B.V.Inventor: Mohammad Moniruzzaman
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Patent number: 9249023Abstract: In some embodiments, the present disclosure pertains to methods of forming a solution of single-walled carbon nanotube polyelectrolytes in a liquid crystalline phase. In some embodiments, such methods comprise: (a) providing single-walled carbon nanotube polyelectrolytes; and (b) mixing the single-walled polyelectrolytes with a polar aprotic solvent to form a mixture, where the mixing results in the formation of single-walled carbon nanotubes in the liquid crystalline phase. In some embodiments, the polar aprotic solvent comprises crown ether. In some embodiments, the present disclosure pertains to a method of making single-walled carbon nanotube fibers. Further embodiments of the present disclosure pertain to a method of making a single walled carbon nanotube composite. In some embodiments, the present disclosure pertains to an article comprising neat aligned carbon nanotubes.Type: GrantFiled: March 6, 2014Date of Patent: February 2, 2016Assignee: WILLIAM MARSH RICE UNIVERSITYInventors: Angel A. Marti-Arbona, Chengmin Jiang, Avishek Saha, Matteo Pasquali, Colin Young
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Patent number: 9243118Abstract: Disclosed herein are fiber reinforced thermoplastic composite with desired physical properties, such as high modulus, high stiffness and high flow while maintaining the OSU heat release compliancy.Type: GrantFiled: June 7, 2012Date of Patent: January 26, 2016Assignee: SABIC Global Technologies B.V.Inventor: Mohammad Moniruzzaman
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Patent number: 9214680Abstract: Electrocatalyst durability has been recently recognized as one of the most important issues that have to be addressed before the commercialization of the proton exchange membrane fuel cells (PEMFCs). The present invention is directed to a new class of cathode catalysts based on supportless platinum nanotubes (PtNTs) and platinum alloy nanotubes, for example, platinum-palladium nanotubes (PtPdNTs), that have remarkable durability and high catalytic activity. Due to their unique combination of dimensions at multiple length scales, the platinum nanotubes of the present invention can provide high platinum surface area due to their nanometer-sized wall thickness, and have the potential to eliminate or alleviate most of the degradation pathways of the commercial carbon supported platinum catalyst (Pt/C) and unsupported platinum-black (PtB) as a result of their micrometer-sized length.Type: GrantFiled: February 24, 2007Date of Patent: December 15, 2015Assignee: The Regents of the University of CaliforniaInventors: Yan Yushan, Zhongwei Chen
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Patent number: 9200804Abstract: A device for effectively removing organic compounds from air by a carbon nanotube-catalyst composite having the two functions of an adsorption/catalytic incineration agent is provided. The carbon nanotube-catalyst composite simultaneously adsorbs the organic compounds and completely decomposes them by a catalytic reaction, and the optimal reaction active temperature by catalytic incineration is low. The carbon nanotube-catalyst composite has a large surface area and has high adsorption performance and catalytic decomposition activity, and is thus applicable to filters that use the methods of adsorption and/or catalytic incineration. The device for removing organic compounds from air includes an adsorption/catalytic incineration reactor including the carbon nanotube-catalyst composite to remove organic compounds from air.Type: GrantFiled: November 24, 2011Date of Patent: December 1, 2015Assignee: BIONEER CORPORATIONInventors: Han Oh Park, Young-Mi Koo, Jae Ha Kim, Yang Won Lee
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Patent number: 9174842Abstract: The present invention discloses a nanocomposite material having single-walled aluminosilicate nanotube in polymer, a membrane comprising such nanocomposite material, and the method of making the nanocomposite material, in which the composite material has high volume fraction of well-dispersed nanotubes. A gel-phased single-walled aluminosilicate nanotube is first prepared and then mixed with a polymer matrix to yield the composite material.Type: GrantFiled: September 10, 2012Date of Patent: November 3, 2015Assignee: Georgia Tech Research CorporationInventors: Sankar Nair, Dun-Yen Kang, Christopher W. Jones
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Patent number: 9121112Abstract: The invention is directed to carbon fibers having high tensile strength and modulus of elasticity. The invention also provides a method and apparatus for making the carbon fibers. The method comprises advancing a precursor fiber through an oxidation oven wherein the fiber is subjected to controlled stretching in an oxidizing atmosphere in which tension loads are distributed amongst a plurality of passes through the oxidation oven, which permits higher cumulative stretches to be achieved. The method also includes subjecting the fiber to controlled stretching in two or more of the passes that is sufficient to cause the fiber to undergo one or more transitions in each of the two or more passes. The invention is also directed to an oxidation oven having a plurality of cooperating drive rolls in series that can be driven independently of each other so that the amount of stretch applied to the oven in each of the plurality of passes can be independently controlled.Type: GrantFiled: October 7, 2014Date of Patent: September 1, 2015Assignee: Hexcel CorporationInventor: Carlos A. León y León
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Patent number: 9117945Abstract: Disclosed are a carbon nano-tube (CNT) thin film treated with chemical having an electron withdrawing functional group and a manufacturing method thereof. Specifically, the CNT thin film comprises a CNT composition to be applied on a plastic substrate. The CNT composition comprises a CNT; and chemical connected to the CNT and having an electron withdrawing functional group. In addition, the method for manufacturing a CNT thin film comprises steps of preparing a CNT; treating the CNT with chemical having an electron withdrawing functional group; mixing the CNT treated with the chemical with a dispersing agent or dispersing solvent to prepare a CNT dispersed solution; and forming a CNT thin film with the CNT dispersed solution. According to the CNT thin film and the manufacturing method thereof, a resistance of an electrode is decreased to improve the electric conductivity of the electrode.Type: GrantFiled: February 14, 2008Date of Patent: August 25, 2015Assignee: SAMSUNG ELECTRONICS CO., LTD.Inventors: Hyeon Jin Shin, Seonmi Yoon, Jaeyoung Choi, Young Hee Lee, Seong Jae Choi, Soo Min Kim
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Patent number: 9096784Abstract: The exemplary embodiments of the present invention provide an apparatus and a thermal interface material with aligned graphite nanofibers in the thermal interface material to enhance the thermal interface material performance. The thermal interface material having a thickness between a first surface and a second surface opposite the first surface. The comprising thermal interface material includes a plurality of carbon nanofibers (CNFs), wherein a majority of the CNFs are oriented orthogonal to a plane of the first surface. The apparatus includes the thermal interface material, and a first object having a third surface; and a second object having a fourth surface; wherein the thermal interface material is sandwiched between the third surface and the fourth surface.Type: GrantFiled: February 23, 2013Date of Patent: August 4, 2015Assignee: International Business Machines CorporationInventors: Joseph Kuczynski, Arvind Kumar Sinha, Kevin Albert Splittstoesser, Timothy Jerome Tofil
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Patent number: 9095639Abstract: The invention is directed to carbon nanostructure composite systems which may be useful for various applications, including as dry adhesives, electronics and display technologies, or in a wide variety of other areas where organized nanostructures may be formed and integrated into a flexible substrate. The present invention provides systems and methods wherein organized nanotube structures or other nanostructures are embedded within polymers or other flexible materials to provide a flexible skin-like material, with the properties and characteristics of the nanotubes or other nanostructures exploited for use in various applications. In one aspect, the invention is directed to a carbon nanotube/polymer composite material having a plurality of carbon nanotubes formed into a predetermined architecture, with each of the plurality of nanotubes having a desired width and length.Type: GrantFiled: February 15, 2007Date of Patent: August 4, 2015Assignee: The University of AkronInventors: Pulickel M. Ajayan, Ali Dhinojwala
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Patent number: 9077793Abstract: A carbon nanotube based flexible mobile phone includes a flexible body including a flexible display panel a flexible touch panel, and a communicating system received therein. The flexible touch panel is disposed on a surface of the flexible display panel. The flexible touch panel includes at least one carbon nanotube layer including a carbon nanotube film.Type: GrantFiled: December 10, 2009Date of Patent: July 7, 2015Assignees: Tsinghua University, HON HAI PRECISION INDUSTRY CO., LTD.Inventors: Kai-Li Jiang, Liang Liu, Qun-Qing Li, Shou-Shan Fan
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Patent number: 9045343Abstract: Syntheses of carbon nanotubes (CNT) are disclosed. The syntheses can take place on a thermally oxidized silicon surface placed inside a furnace prior to a reaction. The setup can have many variables that could affect the resulting CNT arrays, including flow rate and composition of carrier gas, flow rate and composition of precursor solution, and temperature. By varying such variables the density of the resulting CNT arrays can be controlled.Type: GrantFiled: June 7, 2012Date of Patent: June 2, 2015Assignee: CALIFORNIA INSTITUTE OF TECHNOLOGYInventors: Jordan R. Raney, Chiara Daraio
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Publication number: 20150140264Abstract: A method for making a variable-density carbon nanotube film is provided. A drawn carbon nanotube film, including a number of carbon nanotubes aligned along an aligned direction, is prepared. A number of thin regions are formed in the drawn carbon nanotube film along the aligned direction by reducing density of carbon nanotubes in each of the plurality of thin regions. A variable-density carbon nanotube film is provided and includes a number of thin regions and at least one normal region having a density of carbon nanotubes greater than that of the thin regions. The at least one normal region includes a number of carbon nanotubes substantially aligned along an aligned direction. The thin regions are arranged in the form of at least one row extending along the aligned direction.Type: ApplicationFiled: December 3, 2014Publication date: May 21, 2015Inventor: LIANG LIU
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Publication number: 20150132212Abstract: Methods of forming carbon films, structures and devices including the carbon films, and systems for forming the carbon films are disclosed. A method includes depositing a metal carbide film using atomic layer deposition (ALD). Metal from the metal carbide film is removed from the metal carbide film to form a carbon film. Because the films are formed using ALD, the films can be relatively conformal and can have relatively uniform thickness over the surface of a substrate.Type: ApplicationFiled: November 13, 2013Publication date: May 14, 2015Applicant: ASM IP Holding B.V.Inventor: Jereld Lee Winkler
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Patent number: 9028790Abstract: Provided is an aggregate of carbon nanotubes wherein a mixture of 10 mg of aggregate of carbon nanotubes, 30 mg of sodium polystyrene sulfonate and 10 mL of water is subjected to ultrasonic homogenizer treatment, subsequently subjected to centrifugal treatment at 20000 G, then 9 mL of supernatant is sampled, and the content of aggregate of carbon nanotubes in the supernatant is 0.6 mg/mL or more. The aggregate of carbon nanotubes of the present invention can provide a dispersion of an aggregate of carbon nanotubes having a high concentration through very good dispersibility.Type: GrantFiled: February 19, 2008Date of Patent: May 12, 2015Assignee: Toray Industries, Inc.Inventors: Kenichi Sato, Masahito Yoshikawa, Shuko Ikeuchi
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Publication number: 20150125380Abstract: In one aspect of the invention, a method for growth of carbon nanotubes includes providing a graphitic composite, decorating the graphitic composite with metal nanostructures to form graphene-contained powders, and heating the graphene-contained powders at a target temperature to form the carbon nanotubes in an argon/hydrogen environment that is devoid of a hydrocarbon source. In one embodiment, the target temperature can be as low as about 150° C. (±5° C.).Type: ApplicationFiled: November 3, 2014Publication date: May 7, 2015Inventors: Alexandru S. Biris, Enkeleda Dervishi
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Publication number: 20150118142Abstract: Carbon fibers made by a process using a precursor that is a CNT/PAN material blend including CNTs functionalized with a nucleophilic material; and carbon fibers made with such a process.Type: ApplicationFiled: October 5, 2012Publication date: April 30, 2015Inventors: Christopher Allen Dyke, Zohar Ophir
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Publication number: 20150118141Abstract: Carbon fibers made by a process using an organogel precursor that includes a nucleophilic filler and polyacrylonitrile; such a process which includes dry-jet wet spinning; and an article made from such carbon fibers.Type: ApplicationFiled: October 5, 2012Publication date: April 30, 2015Applicants: NANORIDGE MATERIALS, INCORPORATEDInventor: Christopher Allen Dyke
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Publication number: 20150110704Abstract: The present invention provides a method for preparing carbon nanotube fibers with improved spinning properties using a surfactant and carbon nanotube fibers prepared by the method. According to the method for preparing carbon nanotube fibers of the present invention, the addition of a surfactant during the preparation of carbon nanotubes interrupts and delays the agglomeration of catalyst particles, which reduces the size of the catalyst particles and uniformly disperses the catalyst particles that play a key role in the formation of carbon nanotube fibers, thus increasing the strength and conductivity of carbon nanotube fibers and improving the spinning properties. While convention methods prepare carbon nanotube fibers by injecting a catalytic material for the synthesis of carbon nanotubes in a high-pressure supercritical state to be uniformly dispersed, the present invention uses a dispersant and thus does not require the injection in a high-pressure supercritical state.Type: ApplicationFiled: December 26, 2012Publication date: April 23, 2015Applicant: Soongsil University Research Consortium Techno- ParkInventors: Young Jin Jeong, Jun Young Song, So Young Kim, So Ra Yoon, Yeon Su Jung
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Patent number: 8999876Abstract: Catalyst compositions comprising molybdenum, sulfur and an alkali metal ion supported on a nanofibrous, mesoporous carbon molecular sieve are useful for converting syngas to higher alcohols. The compositions are produced via impregnation and may enhance selectivity to ethanol in particular.Type: GrantFiled: December 1, 2011Date of Patent: April 7, 2015Assignee: Georgia Tech Research CorporationInventors: Christopher W. Jones, Pradeep K. Agrawal, Tien Thao Nguyen