Iron-oxygen Compound Containing Patents (Class 252/62.56)
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Publication number: 20130302428Abstract: A process for the preparation of carbon protected superparamagnetic or magnetic nanospheres is claimed which comprises the steps: (A) coating FexOy particles with an organic polymer, (B) coating the product obtained in step (A) with silica, (C) subjecting the product of step (B) to pyrolysis conditions, and (D) removing silica. According to present process, structurally stable carbon protected magnetic nanospheres were obtained, which can be dispersed in various solvents like water, EtOH, toluene, etc.Type: ApplicationFiled: November 9, 2011Publication date: November 14, 2013Applicants: DALIAN UNIVERSITY OF TECHNOLOGY, STUDIENGESELLSCHAFT KOHLE MBHInventors: Ferdi Schueth, Mathias Feyen, An-Hui Lu, Wen-Cui Li, Guang-Hui Wang, Tao Sun
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Publication number: 20130299732Abstract: Disclosed is a hybrid filler for an electromagnetic shielding composite material and a method of manufacturing the hybrid filler, by which electromagnetic shielding and absorbing capabilities are improved and heat generated by electromagnetic absorption is effectively removed. The hybrid filler for an electromagnetic shielding composite material includes an expandable graphite (EG) having a plurality of pores, and magnetic particles integrated with a carbon nanotube (CNT) on outer surfaces thereof in a mixed manner, wherein the magnetic particles are inserted into the pores of the EG.Type: ApplicationFiled: July 24, 2012Publication date: November 14, 2013Applicant: HYUNDAI MOTOR COMPANYInventors: Jin Woo Kwak, Kyong Hwa Song, Han Saem Lee, Byung Sam Choi
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Patent number: 8574450Abstract: Highly pure iron oxides are prepared by reaction of metallic iron, in the form of microspheroidal particles or of scraps or cuttings, with an agitated aqueous solution of a mono- or polycarboxylic acid with a pKa of 0.5 to 6 relative to the first carboxyl and capable of decomposing, by heating in air at 200 to 350° C., to carbon dioxide and water, using 0.03 to 1.5 moles of acid per g-atoms of iron, a water/iron weight ration of 1 to 20, and by oxidation of the ferrous carboxilate to ferric salt, with an agent selected from oxygen, mixtures containing oxygen, hydrogen peroxide, organic peroxides and hydroperoxides.Type: GrantFiled: May 24, 2011Date of Patent: November 5, 2013Assignee: SUD Chemie MT S.r.l.Inventors: Esterino Conca, Carlo Rubini, Guido Petrini
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Publication number: 20130272965Abstract: Provided are a mussel adhesive protein-mimetic dispersion stabilizing agent to disperse nanoparticles in an aqueous medium, a colloidal solution including nanoparticles dispersed and stabilized by the dispersion stabilizing agent, and a contrast agent including the colloidal solution. More particularly, the mussel adhesive protein-mimetic dispersion stabilizer is a polyethyleneimine-graft-(poly-ethyleneglycol;polyDOPA) PEI-graft-(PEG;PDOPA). The graft polymer is formed of two parts. One is polyethyleneglycol grafted with a polyethyleneime which has an affinity to an aqueous medium, and the other is polyDOPA which has an affinity to the surface of nanoparticles. Because of those characteristics, the stabilizer shows a stable dispersion of nano particles in the aqueous medium.Type: ApplicationFiled: December 28, 2011Publication date: October 17, 2013Applicant: HANWHA CHEMICAL CORPORATIONInventors: Taeghwan Hyeon, Kun Na, Daishun Ling, Wooram Park
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Publication number: 20130257035Abstract: The present invention is related to magnetic pigments comprising a transparent flaky homogeneously composed substrate having two parallel major surfaces and a coating comprising a layered structure composed of a hematite and a magnetite layer, to a process for the production of said pigments as well as to their use.Type: ApplicationFiled: November 14, 2011Publication date: October 3, 2013Applicant: MERCK PATENT GMBHInventors: Kaiman Shimizu, Fumiko Sasaki, Yukitaka Watanabe, Masahiko Yazawa
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Publication number: 20130256582Abstract: To provide a ferrite thin film-forming composition material that is a composition material for forming a ferrite thin film by using the sol-gel method which can form a thin ferrite thin film having a uniform thickness and, furthermore, has excellent long-term storage stability, a method of forming a ferrite thin film using the above composition material, and a ferrite thin film formed by using the above method. A ferrite thin film-forming composition material is a composition material for forming a NiZn ferrite, CuZn ferrite, or NiCuZn ferrite thin film by using a sol-gel method, in which the composition material is formed by dissolving metallic raw materials in a solvent including acetonitrile, and the fraction of acetonitrile is 30 mass % to 60 mass % with respect to 100 mass % of the composition material.Type: ApplicationFiled: March 14, 2013Publication date: October 3, 2013Applicant: MITSUBISHI MATERIALS CORPORATIONInventors: Toshihiro Doi, Hideaki Sakurai, Kenzo Nakamura, Kazunori Igarashi, Nobuyuki Soyama
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Patent number: 8545713Abstract: The present invention relates to black magnetic iron oxide particles comprising magnetite as a main component, wherein when the black magnetic iron oxide particles are molded into a tablet shape, an electric resistance value of the tablet in an alternating current electric field is controlled to produce an impedance of not less than 2×106 ?cm as measured in a characteristic frequency range thereof. The black magnetic iron oxide particles according to the present invention can provide a toner capable of exhibiting a good charging performance and a uniform charging property under the high-temperature and high-humidity conditions, so that when developing an electrostatic latent image therewith, it is possible to obtain toner images having a high resolution or definition, and further the use of heavy metal elements in the black magnetic iron oxide particles can be minimized.Type: GrantFiled: March 30, 2010Date of Patent: October 1, 2013Assignee: Toda Kogyo CorporationInventors: Ryo Iwai, Mamoru Kamigaki, Nobuya Shimo, Naoki Uchida
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Publication number: 20130214198Abstract: In order to provide a noise suppression sheet whose imaginary part magnetic permeability ??, representing a magnetic loss component, is large at a GHz-band frequency, thus having an excellent noise suppression effect, the noise suppression sheet comprises a flat magnetic powder having a saturation magnetostriction of 12.0×10?6 or more and 38.0×10?6 or less and an organic binder.Type: ApplicationFiled: February 20, 2013Publication date: August 22, 2013Applicant: NEC TOKIN CORPORATIONInventor: Toshiyuki IGARASHI
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Patent number: 8506837Abstract: A field-responsive fluid which enters a semi-solid state in the presence of an energy field is improved by use of a plurality of energy field responsive particles which form chains in response to the energy field. The particles can be (a) composite particles in which at least one field-responsive member having a first density is attached to at least one member having a second density that is lower than the first density, (b) shaped particles in which at least one field-responsive member has one or more inclusions, and (c) combinations thereof. The particles improve the field-responsive fluid by reducing density without eliminating field-responsive properties which afford utility. Further, a multi-phase base fluid including a mixture of two or more substances, at least two of which are immiscible, may be used.Type: GrantFiled: April 30, 2008Date of Patent: August 13, 2013Assignee: Schlumberger Technology CorporationInventors: Murat Ocalan, Huilin Tu, Nathan Wicks, Agathe Robisson, Dominique Guillot
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Patent number: 8481178Abstract: Oxide-coated Fe powder for producing various electromagnetic circuit components requiring high resistivity is provided. The oxide-coated Fe powder is a Mg-containing oxide film-coated iron powder coated with an Mg—Fe—O ternary-based deposition film at least containing (Mg, Fe)O. The (Mg,Fe)O is a crystalline MgO-dissolving wustite. The Mg—Fe—O ternary-based oxide deposition film has a sulfur-enriched layer containing a higher concentration of sulfur than that of central portion of the iron powder, fine crystalline texture having a grain size of 200 nm or less, and the outermost surface is substantially composed of MgO. A composite soft magnetic material using the Mg-containing oxide film-coated iron powder is also provided.Type: GrantFiled: September 8, 2011Date of Patent: July 9, 2013Assignee: Diamet CorporationInventors: Muneaki Watanabe, Ryoji Nakayama, Gakuji Uozumi
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Publication number: 20130164564Abstract: An aspect of the present invention relates to a method of manufacturing magnetic particles, which comprises: adding a compound to a water-based magnetic liquid, wherein the water-based magnetic liquid comprises magnetic particles dispersed in an acidic water-based solvent, and the compound is selected from the group consisting of amine compounds, aromatic compounds, and aliphatic compounds having one or more monovalent phosphorus polar groups denoted by: wherein m1 denotes 0 or 1, m2 denotes 1 or 2, and M denotes a hydrogen atom or an alkali metal atom; and then collecting the magnetic particles from the water-based magnetic liquid to obtain the magnetic particles the surfaces of which have been modified by being coated with the compound.Type: ApplicationFiled: December 26, 2012Publication date: June 27, 2013Applicant: FUJIFILM CORPORATIONInventor: FUJIFILM Corporation
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Publication number: 20130126394Abstract: The present invention provides a method of preparing an iron oxide magnetic nanoparticle, comprising the steps of: i) reacting a water-soluble ferrous salt with a water-soluble ferric salt in a mole ratio of 1:2 in the presence of a base and a citrate to give an iron oxide particle surface-coated with the citrate (c-MNP); ii) reacting the c-MNP obtained in step (i) with a thiophilic compound to give a thiophilic compound-bounded iron oxide particle surface-coated with the citrate (thiophilic-c-MNP); and iii) modifying the thiophilic-c-MNP obtained in step (ii) using a surfactant for phase transfer of the thiophilic-c-MNP from aqueous phase to organic phase. The present invention also relates to the iron oxide magnetic nanoparticle prepared by the above-mentioned method and the use of the nanoparticle in desulfurization. The iron oxide magnetic nanoparticle of the present invention is capable of effective deep desulfurization.Type: ApplicationFiled: November 8, 2012Publication date: May 23, 2013Applicant: NANOPETRO COMPANY LIMITEDInventor: NANOPETRO COMPANY LIMITED
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Publication number: 20130130035Abstract: The present invention refer to a innovative process for obtaining nanoparticulate magnetic ferrites, at low temperatures, simple or mixed, functionalized by organic molecules, for dispersion of these nanoparticles in polar or nonpolar media, and the same particles dispersed in a liquid medium, also known as ferrofluids. The present invention enables obtaining both simple ferrites (MFe2O4 or MFe12O19) and mixed ferrites (Nx M(1?x)Fe2O4 or N1?Y Mx+Y Fe(2?x)O4; as example) where M and N can be metals, such as Sm, La, Bi, Ba, Mo, Sr, Ni, Fe, Mn, Cr, etc., through the coprecipitation method, functionalized by organic molecules containing carboxylic groups, which are polymers, or long chain acids or short chain acids, containing mono, di or tricarboxylic groups and/or alcohols, whose dispersion in polar or nonpolar media is improved. The present invention enables also obtaining ferrofluids, through the mixture of the obtained magnetic particles with an appropriate liquid carrier.Type: ApplicationFiled: May 3, 2011Publication date: May 23, 2013Applicant: NANUM NANOTECNOLOGIA S/AInventors: Jose Fernando Contadini, Tarik Della Santina Mohallem, Taiane Guedes Fonseca De Souza
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Patent number: 8444872Abstract: Disclosed is a magnetic material having high Hc and High Curie point, which is capable of controlling such magnetic characteristics without requiring rare or expensive raw materials. Specifically disclosed is a magnetic material composed of particles of a magnetic iron oxide which is represented by the following general formula: ?-AxByFe2?x?yO3 or ?-AxByCzFe2?x?y?zO3 (wherein A, B and C each represents a metal excluding Fe and different from each other, satisfying 0<x, y, z<1), with ?-Fe2O3 as a main phase.Type: GrantFiled: May 30, 2008Date of Patent: May 21, 2013Assignees: The University of Tokyo, Dowa Electronics Materials Co., Ltd.Inventors: Shin-ichi Ohkoshi, Shunsuke Sakurai, Takenori Yorinaga, Kazuyuki Matsumoto, Shinya Sasaki
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Publication number: 20130112605Abstract: Novel chromatographic materials for chromatographic separations, columns, kits, and methods for preparation and separations with a superficially porous material comprising a substantially nonporous core and one or more layers of a porous shell material surrounding the core. The material of the invention is comprised of superficially porous particles and a narrow particle size distrution.Type: ApplicationFiled: July 25, 2011Publication date: May 9, 2013Applicant: Waters Technologies CorporationInventors: Kevin D. Wyndham, Beatrice W. Muriithi, Michael F. Morris, Nicole L. Lawrence
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Patent number: 8435496Abstract: A method for providing nanoparticle clusters of controlled dimensions is described. The method involves an activation of individual nanoparticles and the subsequent interaction between activated particles to form a cluster.Type: GrantFiled: December 12, 2007Date of Patent: May 7, 2013Assignee: Dublin City UniversityInventors: Dermot Brougham, Swapankumar Ghosh
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Publication number: 20130099152Abstract: This invention relates to a manufacturing method of colloid comprising magnetic nanoclusters and magnetic nanocluster colloid made by the same. More particularly, this invention relates to a manufacturing method of colloid comprising magnetic nanoclusters comprising magnetic precursor and heterometal precursor by a certain ratio and magnetic nanocluster colloid made by the same.Type: ApplicationFiled: April 5, 2011Publication date: April 25, 2013Applicants: NANOBRICK CO., LTD., SUN R & D BInventors: Jin Kyu Lee, Jin Myung Cha
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Publication number: 20130099153Abstract: A hybrid material including graphene and iron oxide, a method of manufacturing the same, and an apparatus for treating waste water using the same are provided. A hybrid material having magnetic properties and high dispersibility and including graphene and iron oxide may be effectively used for removing a heavy metal in waste water.Type: ApplicationFiled: October 23, 2011Publication date: April 25, 2013Applicant: POSTECH ACADEMY-INDUSTRY FOUNDATIONInventors: Kwang Soo KIM, Jung Woo Lee, Chandra Vimlesh, In Chul Hwang, Young Chun
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Patent number: 8419966Abstract: An aspect of the present invention relates to a method of manufacturing a hexagonal ferrite magnetic powder comprising preparing a melt by melting a starting material mixture comprising a hexagonal ferrite-forming component and a glass-forming component; rapidly cooling the melt to obtain an amorphous material comprising 0.3 to 2.0 weight percent of carbon atoms; heating the amorphous material to a temperature range of 580 to 700° C. and maintaining the amorphous material within the temperature range to precipitate hexagonal ferrite magnetic particles; and collecting the hexagonal ferrite magnetic particles precipitated.Type: GrantFiled: March 30, 2010Date of Patent: April 16, 2013Assignee: FUJIFILM CorporationInventors: Shiho Kamisawa, Toshio Tada, Nobuo Yamazaki
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Patent number: 8416051Abstract: A magnetic material constituted by a grain-compacted body comprising a plurality of metal grains made of a Fe—Si—M soft magnetic alloy (where M is a metal element more easily oxidized than Fe) and an oxide film formed on the surface of the metal grains; wherein there are bonding portions via the oxide film formed on the surfaces of adjacent metal grains and direct bonding portions of metal grains in locations where the oxide film is not present.Type: GrantFiled: December 7, 2011Date of Patent: April 9, 2013Assignee: Taiyo Yuden Co., Ltd.Inventors: Hitoshi Matsuura, Kenji Otake
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Publication number: 20130075649Abstract: A magnetic glue includes a curable glue and magnetic nanoparticles mixed in the curable glue. The magnetic glue is used in a lens module to avoid polluting the optical portion of the lens module.Type: ApplicationFiled: December 29, 2011Publication date: March 28, 2013Applicant: HON HAI PRECISION INDUSTRY CO., LTD.Inventor: CHIEN-CHUN WANG
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Patent number: 8404338Abstract: An article and thermoplastic composition including polycarbonate, a polysiloxane-polycarbonate and an x-ray detectable or metal detectable agent having good magnetic permeability and/or electrical conductivity wherein the composition may be used in articles for food preparation. The thermoplastic compositions are useful in forming molds for manufacturing a food product, such as chocolate molds.Type: GrantFiled: September 30, 2009Date of Patent: March 26, 2013Assignee: Sabic Innovative Plastics IP B.V.Inventors: Christopher Luke Hein, Jan-Pleun Lens, Vandita Pai-Paranjape, Constant Peek, Robert Dirk van de Grampel
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Patent number: 8398880Abstract: An aspect of the present invention relates to a method of modifying a surface of a powder, comprising mixing a powder with a compound denoted by general formula (I): wherein, in general formula (I), each of R10 and R13 independently denotes a hydrogen atom, alkyl group, or aryl group, each of R11 and R12 independently denotes an alkyl group or an aryl group, and L denotes a single bond or an oxygen atom.Type: GrantFiled: August 26, 2009Date of Patent: March 19, 2013Assignee: FUJIFILM CorporationInventor: Kazufumi Omura
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Publication number: 20130062286Abstract: The present invention relates to a method for obtaining materials based on treating solids by interaction with ferrofluids to give the final product a superparamagnetic behaviour at a moderate temperature. Said superparamagnetic materials are the result of the assembly of metal oxide nanoparticles associated to a compound with a surfactant effect, such as oleic acid, which are provided by a non-aqueous ferrofluid to different types of solids, preferably having adsorbent, absorbent or reactant and product support properties. The invention also relates to the material obtained by this procedure and its use in various applications such as adsorbents, sensors, ion exchangers the removal of toxic or radioactive contaminants, in chromatographic separation processes, in medical and biological applications, as carriers of biologically derived materials such as enzymes, as polymer fillers, absorption of electromagnetic radiation, as well as metal oxide and catalyst precursors.Type: ApplicationFiled: March 7, 2011Publication date: March 14, 2013Applicant: CONSEJO SUPERIOR DE INVESTIGACIONES CIENTIFICAS (CSIC)Inventors: Eduardo Ruiz Hitzky, María Pilar Aranda Gallego, Yorexis González Alfaro
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Publication number: 20130033354Abstract: Disclosed herein are a ferrite powder having a core-shell structure, the core being made of iron (Fe) or iron-based compounds comprising iron (Fe) and the shell being made of metal oxides, a ferrite material comprising the ferrite powder and the glass, and multilayered chip components including the ferrite layer using the ferrite material, inner electrodes, and outer electrodes. According to the exemplary embodiments of the present invention, it is possible to provide the ferrite material capable of improving the change in the inductance L value in response to applied current by suppressing magnetization at high current. The multilayered chip components including the ferrite material according to the exemplary embodiment of the present invention can also be used in a band of MHz.Type: ApplicationFiled: August 1, 2012Publication date: February 7, 2013Inventors: Sung Yong An, Myeong Gi Kim, Ic Seob Kim
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Publication number: 20130027808Abstract: An aspect of the present invention relates to a magnetic tape comprising a magnetic layer containing a hexagonal ferrite magnetic powder and a binder on a nonmagnetic support, wherein a standard deviation ?Hk of a magnetic anisotropy constant Hk of the magnetic layer is equal to or less than 30%, and a magnetic interaction ?M as calculated by equation (1) below falls within a range of ?0.20??M??0.03: ?M=(Id(H)+2Ir(H)?Ir(?))/Ir(?) . . . (1) wherein Id(H) denotes a residual magnetization measured with DC demagnetization, Ir(H) denotes a residual magnetization measured with AC demagnetization, and Ir(?) denotes a residual magnetization measured at an applied magnetic field of 796 kA/m.Type: ApplicationFiled: July 24, 2012Publication date: January 31, 2013Applicant: FUJIFILM CORPORATIONInventor: Norihito KASADA
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Publication number: 20120286920Abstract: A composite material can include a grain component and a nanostructured grain boundary component. The nanostructured grain boundary component can be insulating and magnetic, so as to provide greater continuity of magnetization of the composite material. The grain component can have an average grain size of about 0.5-50 micrometers. The grain boundary component can have an average grain size of about 1-100 nanometers. The nanostructured magnetic grain boundary material has a magnetic flux density of at least about 250 mT. The grain component can comprise MnZn ferrite particles. The nanostructured grain boundary component can comprise NiZn ferrite nanoparticles. Core components and systems thereof can be manufactured from the composite material.Type: ApplicationFiled: May 8, 2012Publication date: November 15, 2012Inventors: Yajie Chen, Vincent G. Harris
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Publication number: 20120270043Abstract: An adhesive composition for slide rail exhibits excellent workability in attaching a slide rail to a vehicle body and has a strong adhesive force after heating, the magnetic force of which can be lowered, which sustains the strong adhesive force after heating and then returning to room temperature so as to allow the firm fixation of the slide rail to the vehicle body, and which can lower the volume of the noise caused by opening/closing of a door. Specifically disclosed is an adhesive composition for slide rail which includes a hot-melt adhesive and a ferromagnetic substance, wherein the composition shows a density at 20° C. of 1.4-4.5 g/cm3 and has such magnetic properties that the magnetic force of an adhesive sheet, that is obtained by molding the composition, at a position 1 cm apart from the surface of the adhesive sheet is 10 mT or more.Type: ApplicationFiled: September 3, 2010Publication date: October 25, 2012Applicant: LINTEC CORPORATIONInventors: Yoshitomo Ono, Tadahiro Tominou, Yumiko Amino, Shigeyuki Yaguchi
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Publication number: 20120261606Abstract: A pearlescent pigment and a process for enhancing the magnetic properties of a pearlescent pigment. The pearlescent pigment has a layer with regions of ?-Fe2O3 and regions of ?-Fe2O3. The magnetic properties of a pearlescent pigment may be enhanced by the steps of: providing a platelet pigment with a layer of Fe2O3, with a magnetic susceptibility less than 0.1×10?5 m3/kg; reducing some or all of the Fe2O3 to Fe3O4; and oxidizing some or all of the Fe3O4 to ?-Fe2O3. The color difference (?E*) between the provided pigment and the resultant pigment is not more than about 5.Type: ApplicationFiled: June 26, 2012Publication date: October 18, 2012Inventors: Aaron M. Hollman, Philippe Schottland
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Patent number: 8282852Abstract: A magnetorheological (MR) fluid is described herein. The MR fluid includes a plurality of magnetizable particles having a particle density. The fluid also includes a carrier fluid having a fluid density, and the plurality of magnetizable particles is dispersed within the carrier fluid. A portion of the plurality of magnetizable particles has a particle density that is substantially the same as the fluid density. The MR fluid may include a plurality of magnetizable particles having an outer shell of a magnetizable material and a hollow core. The MR fluid may also include a plurality of magnetizable particles having an outer shell of a magnetizable material and a solid core. The MR fluid may include a plurality of magnetizable particles having a matrix and a plurality of sub-particles embedded therein. The core or matrix of these particles may include a ceramic, glass or polymer, or a combination thereof.Type: GrantFiled: September 16, 2009Date of Patent: October 9, 2012Assignee: GM Global Technology Operations LLCInventor: Prabhakar Marur
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Publication number: 20120249375Abstract: A material contains a curable liquid polymer containing suspended nanoparticles capable of exhibiting a magnetic property. The nanoparticles are present in a concentration sufficient to cause the curable liquid polymer to flow in response to application of a magnetic field, enabling the material to be guided into narrow regions to completely fill such regions prior to the polymer being cured. A method includes applying a filler material to at least one component, the filler material including a heat curable polymer containing nanoparticles, and applying an electromagnetic field to at least part of the filler material. The nanoparticles contain a core capable of experiencing localized heating sufficient to at least partially cure surrounding polymer. Also disclosed is an assembly for use at radio frequencies. The assembly includes a substrate and at least one component supported by the substrate.Type: ApplicationFiled: May 23, 2008Publication date: October 4, 2012Inventors: Markku T. Heino, Reijo K. Lehtiniemi, Markku A. Oksanen, Eira T. Seppala, Pekka Martti Tapio Ikonen, Robin H.A. Ras, Jaakko Timonen, Maija Pohjakallio, Christoffer Johans
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Publication number: 20120248368Abstract: This invention relates to a magnetic ceramic material comprising, as main components, (a) at least one magnetic iron oxide selected from the group consisting of Fe3O4 and ?-Fe2O3, and (b) an amorphous phase, and a process for producing a magnetic ceramic material, comprising (1) heating a microorganism-derived iron oxide ceramic material containing an iron atom, and (2) reducing the iron oxide ceramic material obtained in Step (1) by heating in the presence of hydrogen gas.Type: ApplicationFiled: December 14, 2010Publication date: October 4, 2012Inventors: Jun Takada, Hideki Hashimoto, Tatsuo Fujii, Makoto Nakanishi
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Publication number: 20120251844Abstract: An aspect of the present invention relates to magnetic recording powder, which comprises hexagonal ferrite magnetic particles, the hexagonal ferrite magnetic particle comprising 0.5 to 5.0 atomic percent of an Fe substitution element in the form of just a divalent element per 100 atomic percent of a content of Fe and having an activation volume ranging from 1,200 to 1,800 nm3.Type: ApplicationFiled: March 27, 2012Publication date: October 4, 2012Applicant: FUJIFILM CORPORATIONInventors: Nobuo YAMAZAKI, Toshio TADA, Hiroyuki SUZUKI
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Publication number: 20120247461Abstract: A sorbing granular material (20) is provided including a plurality of particles of granular material (5). The particles of granular material (5) are mixed at least partly with magnetizable particles (10), so that in case of magnetization of the magnetizable particles (10), the particles of granular material (5) form a compacted sorbing granular material (20) based on magnetic attracting forces between the magnetizable particles (10). The compaction is reversible. In addition, a process for producing a sorbing granular material (20) is provided.Type: ApplicationFiled: September 23, 2011Publication date: October 4, 2012Applicant: DRÄGER SAFETY AG & CO. KGAAInventors: Jürgen UNGER, Annette KOSEGARTEN
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Patent number: 8277690Abstract: The present invention provides a conducting copolymer ferromagnetic composite. Particularly, the present invention relates to a conducting copolymer of aniline and ethylene-dioxy thiophene containing ferrite particles. The present invention also provides insitu polymerization of aniline and ethylene-dioxy thiophene in the presence of ferrite particles and suitable surfactant medium. This conducting copolymer ferromagnetic composite can be used for the dissipation of electrostatic charge, for the shielding of electromagnetic interference and as absorbing of electromagnetic waves in the microwave region.Type: GrantFiled: May 4, 2009Date of Patent: October 2, 2012Assignee: Council of Scientific & Industrial ResearchInventors: Sundeep Kumar Dhawan, Kuldeep Singh, Nikhil Sobti, Anil Ohlan, Parveen Saini, Beena Gupta, Rajendra Prasad Pant, Ravinder Kumar Kotnala, Kishan Hari, Prafulla Chandra Kothari
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Publication number: 20120225264Abstract: A magnetic fluid composition include a suspension of nano-particles including cross-crystallized multi-metal compounds dispersed in a solvent, the cross-crystallized multi-metal compounds including at least two or more metals having different valencies or oxidation states, the metals selected from the group consisting of a monovalent metal (Me+), a divalent metal (Me2+), a trivalent metal (Me3+), a quadrivalent metal (Me4+) and a rare earth metal. The magnetic fluid having a viscosity and surface tension that permits dispensing from an inkjet printer at a rate of at least 2.5 m/s, at a resolution of at least 600 dpi, supporting jetting pulse frequencies of at least 15 KHz per nozzle (enabling high speed inkjet printing applications of at least 0.6 m/sec per individual nozzle row per print head), and enabling uninterrupted, industrial level print output of magnetic ink character recognition (MICR) code lines suitable for high speed magnetic data scanning per established industry regulations (ANSI X9).Type: ApplicationFiled: March 1, 2012Publication date: September 6, 2012Inventor: Thomas Villwock
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Patent number: 8236192Abstract: An ink including stabilized magnetic single-crystal nanoparticles, wherein the value of the magnetic anisotropy of the magnetic nanoparticles is greater than or equal to 2×104 J/m3. The magnetic nanoparticle may be a ferromagnetic nanoparticle, such as FePt. The ink includes a magnetic material that minimizes the size of the particle, resulting in excellent magnetic pigment dispersion stability, particularly in non-aqueous inkjet inks. The smaller sized magnetic particles of the ink also maintains excellent magnetic properties, thereby reducing the amount of magnetic particle loading required in the ink.Type: GrantFiled: June 26, 2008Date of Patent: August 7, 2012Assignee: Xerox CorporationInventors: Marcel P. Breton, Richard P. N. Veregin, Karen A. Moffat, Peter M. Kazmaier, Patricia A. Burns, Paul F. Smith
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Patent number: 8226845Abstract: A fluid includes a liquid medium having iron particles mixed therein. An organic phosphonate based coating is established on the iron particles. The organic phosphonate based coating does not substantially include phosphonic acid groups at an outer surface thereof, and increases oxidation resistance of the iron particles. A method of making such a liquid medium is also disclosed herein.Type: GrantFiled: October 27, 2008Date of Patent: July 24, 2012Assignee: GM Global Technology Operations LLCInventors: Andrew M. Mance, Keith S. Snavely, Mark A. Golden, John C. Ulicny
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Publication number: 20120168671Abstract: Compositions comprising nanosized objects (i.e., nanoparticles) in which at least one observable marker, such as a radioisotope or fluorophore, is incorporated within the nanosized object. The nanosized objects include, for example, metal or semi-metal oxide (e.g., silica), quantum dot, noble metal, magnetic metal oxide, organic polymer, metal salt, and core-shell nanoparticles, wherein the label is incorporated within the nanoparticle or selectively in a metal oxide shell of a core-shell nanoparticle. Methods of preparing the volume-labeled nanoparticles are also described.Type: ApplicationFiled: December 30, 2010Publication date: July 5, 2012Applicant: UT-BATTELLE, LLCInventors: Wei Wang, Baohua Gu, Scott T. Retterer, Mitchel J. Doktycz
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Patent number: 8211224Abstract: A pearlescent pigment comprising a substrate and a first layer, wherein the first layer comprises iron oxide, wherein the iron has from about 1% to about 30% Fe(II) and from about 70% to about 99% Fe(III). A process for making these pearlescent pigment, comprise reducing a metal oxide substrate with a hydrogen source in the presence of a noble metal catalyst in a liquid medium. The pigments may be used in a variety of applications including cosmetics, plastics, automotive, or architectural coatings.Type: GrantFiled: October 31, 2007Date of Patent: July 3, 2012Assignee: Sun Chemical Corp.Inventors: Aaron M. Hollman, Stephane Nicolas, Philippe Schottland, Marguerite Debacker, Aurelie Antonowicz, Hai Hui Lin
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Publication number: 20120161062Abstract: An object of the present invention is to provide a ferrite magnetic material which can provide a permanent magnet retaining high Br and HcJ as well as having high Hk/HcJ. The ferrite magnetic material according to a preferred embodiment is a ferrite magnetic material formed of hard ferrite, wherein a P content in terms of P2O5 is 0.001% by mass or more.Type: ApplicationFiled: July 2, 2010Publication date: June 28, 2012Applicant: TDK CorporationInventors: Junichi Nagaoka, Takahiro Mori, Hiroyuki Morita, Yoshihiko Minachi
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Patent number: 8206545Abstract: A curable composition comprising magnetically active elastic microspheres that are filled with a curing agent. The elastomeric microspheres are predispersed throughout the curable resin and are magnetostrictive. Cure of the adhesive is initiated when an external magnetic field is applied that physically distorts or ruptures the magnetic microspheres due to a magnetostrictive effect from the magnetic field.Type: GrantFiled: November 13, 2009Date of Patent: June 26, 2012Assignee: Lord CorporationInventor: J. David Carlson
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Publication number: 20120145945Abstract: A process for the production of magnetic nanoparticles on a continuous basis from aqueous salt solutions, utilizes very rapid mixing of the reaction components to achieve particles with a uniform size and shape as well as narrow size distribution. The process includes a methodology to determine the necessary experimental conditions to achieve a sufficiently rapid mix of the reaction components, based on real-time measurements of the magnetic susceptibility of the precipitate during the precipitation reaction.Type: ApplicationFiled: July 9, 2010Publication date: June 14, 2012Inventors: Valter Strom, Richard Olsson
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Patent number: 8192630Abstract: Methods for in-line purification of surfactant from a first fluid, such as a microemulsion are disclosed. Magnetic particles coated with surfactant molecules may be used to bind surfactants from a fluid. A magnetic field may be used to separate the bound materials from the fluid.Type: GrantFiled: December 21, 2010Date of Patent: June 5, 2012Assignee: Empire Technology Development LLCInventor: Angele Sjong
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Publication number: 20120100064Abstract: The present invention provides a process for production of a magnetic thin film which has insulation properties, serves as a permanent magnet, and has improved residual magnetization in comparison with prior arts, the magnetic thin film, and a magnetic material. When a magnetic thin film 3 is formed, an external magnetic field with a predetermined intensity is applied to a coating liquid containing magnetic particles containing epsilon-type iron-oxide-based compounds which have insulation properties and which serve as a permanent magnet, and the coating liquid is let cured in order to form the magnetic thin film 3. Accordingly, the magnetic particles containing the epsilon-type iron-oxide-based compounds can be fixed while being oriented regularly in a magnetization direction. This realizes the process for production of the magnetic thin film 3 which has insulation properties and which serve as a permanent magnet, the magnetic thin film 3, and a magnetic material 1.Type: ApplicationFiled: June 24, 2010Publication date: April 26, 2012Applicant: The University of TokyoInventors: Shin-Ichi Ohkoshi, Asuka Namai, Kazuyuki Takami, Koutaro Tomita
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Publication number: 20120091702Abstract: The present invention is related to magnetic pigments comprising a transparent flaky homogeneously composed substrate having two parallel major surfaces and a coating comprising maghemite, to a process for the production of said pigments as well as to their use.Type: ApplicationFiled: June 8, 2010Publication date: April 19, 2012Applicant: Merck Patent Gesellschaft Mit Beschrankter HaftungInventors: Kaiman Shimizu, Tamio Noguchi, Fumiko Sasaki, Yukitaka Watanabe, Masahiko Yazawa
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Patent number: 8153097Abstract: A method for manufacturing ferrite powder comprises a step (a) of causing a precursor, obtained by a liquid-phase reaction method, to pass through a sieve with openings of 2 mm or less, and a step (b) of causing free fall, through the interior of a furnace tube heated to the range 750 to 1250° C. by a heater, of the precursor which has passed through the sieve. In the process of causing free fall through the interior of the furnace tube heated by the heater, ferrite powder, which is a single phase of hexagonal ferrite, is obtained by heating the precursor to a prescribed temperature and holding the precursor at the prescribed temperature.Type: GrantFiled: September 25, 2008Date of Patent: April 10, 2012Assignee: TDK CorporationInventor: Mamoru Satoh
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Patent number: 8133405Abstract: Spinel-type ferrimagnetic particles having a composition represented by the formula: (MO)·n/2(Fe2O3) where M is a divalent metal and n is a molar ratio of Fe to M (n=Fe/M) which is from more than 2.05 to less than 2.5 (2.05<n<2.5). They contain a superparamagnetic component in an amount of not more than 2% by mass, has an average particle diameter of 5 to 30 nm. The particles are respectively coated on surface with a hydroxide of at least one metal Si, Al, P and Zn in an amount of not more than 10% by mass, calculated as the metal. The spinel-type ferrimagnetic particles can exhibit a high coercive force irrespective of fine particles, and are excellent in dispersibility and chemical stability, as well as the magnetic recording medium for high-density recording can exhibit not only excellent frequency characteristics and high output characteristics, but also an excellent weather resistance and a high reliability.Type: GrantFiled: May 13, 2010Date of Patent: March 13, 2012Assignee: Toda Kogyo CorporationInventors: Hiroshi Yamamoto, Tsutomu Katamoto
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Publication number: 20120058463Abstract: The present invention relates to a stable mixture comprising surface-modified particles which are obtained by reacting metal oxide or semimetal oxide particles with at least one compound selected from among silicon-comprising compounds bearing one, two or three alkoxy radicals and at least one solvent, at least one surface-active substance or a mixture thereof, the use of these particles in systems in which they are brought into contact with at least one solvent, where the mass ratio of solvent to modified particle is greater than 500, and also the use of these particles in agglomeration-deagglomeration cycles.Type: ApplicationFiled: September 2, 2011Publication date: March 8, 2012Applicants: Siemens AG, BASF SEInventors: Stephan DEUERLEIN, Imme Domke, Alexej Michailovski, Reinhold Rieger, Piyada Charoensirisomboon
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Publication number: 20120056121Abstract: A process for making magnetite nanoparticle dispersions by reacting the surface groups of the destructured magnetite ore with carboxyl acid groups of the long chain carboxylic acid to form nanoparticles containing bound stabilizer and dispersing the nanoparticles in alcoholic solvent.Type: ApplicationFiled: July 5, 2011Publication date: March 8, 2012Applicant: Sri Lanka Institute of Nanotechnology (PVT) Ltd.Inventors: Veranja Karunaratne, Gayan Priyadharshana, Sunanda Gunasekara, Nilwala Kottegoda, Atula Senaratne