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公开(公告)号:US06569518B2
公开(公告)日:2003-05-27
申请号:US10147599
申请日:2002-05-17
Applicant: Tapesh Yadav , Ming Au
Inventor: Tapesh Yadav , Ming Au
IPC: B32B516
CPC classification number: H01L23/5328 , A61L27/06 , B01J12/005 , B01J12/02 , B01J19/0046 , B01J19/24 , B01J23/002 , B01J23/08 , B01J23/14 , B01J35/0013 , B01J37/18 , B01J2219/00094 , B01J2219/00135 , B01J2219/00155 , B01J2219/00177 , B01J2219/0018 , B01J2219/00317 , B01J2219/00385 , B01J2219/0043 , B01J2219/00653 , B01J2219/00707 , B01J2219/00745 , B01J2219/00747 , B01J2219/0075 , B01J2219/00754 , B01J2219/00756 , B01J2219/0894 , B01J2523/00 , B05B1/12 , B22F1/0003 , B22F9/04 , B22F9/12 , B22F2009/041 , B22F2998/00 , B22F2999/00 , B29C70/58 , B82B1/00 , B82Y5/00 , B82Y25/00 , B82Y30/00 , C01B3/001 , C01B13/145 , C01B19/007 , C01B21/062 , C01B32/956 , C01B35/04 , C01F5/06 , C01F11/06 , C01F17/0043 , C01G23/006 , C01G25/00 , C01G25/02 , C01G41/02 , C01G53/00 , C01G53/006 , C01P2002/01 , C01P2002/02 , C01P2002/34 , C01P2002/54 , C01P2002/60 , C01P2002/72 , C01P2004/03 , C01P2004/04 , C01P2004/38 , C01P2004/51 , C01P2004/54 , C01P2004/61 , C01P2004/62 , C01P2004/64 , C01P2006/10 , C01P2006/12 , C01P2006/40 , C01P2006/60 , C04B35/00 , C04B35/01 , C04B35/265 , C04B35/2666 , C04B35/453 , C04B35/457 , C04B35/56 , C04B35/5611 , C04B35/581 , C04B35/62222 , C04B41/009 , C04B41/4549 , C04B41/52 , C04B41/87 , C04B41/89 , C04B41/90 , C04B2111/00844 , C04B2235/3241 , C04B2235/3262 , C04B2235/3275 , C04B2235/3279 , C04B2235/3284 , C04B2235/3298 , C04B2235/79 , C04B2235/80 , C08K3/01 , C08K3/08 , C08K2201/011 , C08K2201/016 , G01N27/127 , H01C7/112 , H01C17/0652 , H01F1/0036 , H01F1/0045 , H01F1/36 , H01F41/0246 , H01G4/12 , H01G4/33 , H01L23/49883 , H01L2924/0002 , H01L2924/3011 , H01M4/02 , H01M4/04 , H01M4/242 , H01M4/581 , H01M4/5815 , H01M4/582 , H01M4/8875 , H01M4/8885 , H01M4/90 , H01M4/9066 , H01M8/1213 , H01M8/1246 , H01M8/1253 , H01M10/0562 , H01M10/0566 , Y02E60/324 , Y02E60/525 , Y02P70/56 , Y10S428/90 , Y10S977/762 , Y10S977/783 , Y10S977/81 , Y10S977/811 , Y10S977/948 , Y10T29/4902 , Y10T428/12056 , Y10T428/1216 , Y10T428/12181 , Y10T428/25 , Y10T428/254 , Y10T428/256 , Y10T428/257 , Y10T428/259 , Y10T428/2982 , Y10T428/2991 , Y10T428/2998 , B01J2523/33 , B01J2523/43 , B22F1/0018 , B22F2202/13 , B01J2523/31 , B01J2523/54 , B01J2523/67 , B01J2523/72 , B01J2523/845 , B01J2523/847 , B01J2523/22 , B01J2523/3706 , B01J2523/48 , B01J2523/18 , B01J2523/27 , B01J2523/824 , B01J2523/842 , B01J2523/17 , B01J2523/47 , B01J2523/56 , B01J2523/57 , C04B41/4539 , C04B41/5059 , C04B41/5116 , C04B41/5122 , C04B41/5027 , C04B41/5049 , C04B41/524 , C04B35/10 , B22F2201/11 , B01J2523/305 , B01J2523/69 , H01L2924/00
Abstract: Novel non-ionics and energy device materials made from non-stoichiometric nanomaterials and their applications are discussed. More specifically, the specifications teach the use of nanotechnology and nanostructured materials for developing novel energy related products.
Abstract translation: 讨论了由非化学计量纳米材料制成的新型非离子和能量器件材料及其应用。 更具体地说,该规范教导了纳米技术和纳米结构材料用于开发新型能量相关产品的应用。
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公开(公告)号:US06554609B2
公开(公告)日:2003-04-29
申请号:US10147837
申请日:2002-05-17
Applicant: Tapesh Yadav , Roger Dirstine , John Alexander
Inventor: Tapesh Yadav , Roger Dirstine , John Alexander
IPC: B22F100
CPC classification number: H01L23/5328 , A61L27/06 , B01J12/005 , B01J12/02 , B01J19/0046 , B01J19/24 , B01J23/002 , B01J23/08 , B01J23/14 , B01J35/0013 , B01J37/18 , B01J2219/00094 , B01J2219/00135 , B01J2219/00155 , B01J2219/00177 , B01J2219/0018 , B01J2219/00317 , B01J2219/00385 , B01J2219/0043 , B01J2219/00653 , B01J2219/00707 , B01J2219/00745 , B01J2219/00747 , B01J2219/0075 , B01J2219/00754 , B01J2219/00756 , B01J2219/0894 , B01J2523/00 , B05B1/12 , B22F1/0003 , B22F9/04 , B22F9/12 , B22F2009/041 , B22F2998/00 , B22F2999/00 , B29C70/58 , B82B1/00 , B82Y5/00 , B82Y25/00 , B82Y30/00 , C01B3/001 , C01B13/145 , C01B19/007 , C01B21/062 , C01B32/956 , C01B35/04 , C01F5/06 , C01F11/06 , C01F17/0043 , C01G23/006 , C01G25/00 , C01G25/02 , C01G41/02 , C01G53/00 , C01G53/006 , C01P2002/01 , C01P2002/02 , C01P2002/34 , C01P2002/54 , C01P2002/60 , C01P2002/72 , C01P2004/03 , C01P2004/04 , C01P2004/38 , C01P2004/51 , C01P2004/54 , C01P2004/61 , C01P2004/62 , C01P2004/64 , C01P2006/10 , C01P2006/12 , C01P2006/40 , C01P2006/60 , C04B35/00 , C04B35/01 , C04B35/265 , C04B35/2666 , C04B35/453 , C04B35/457 , C04B35/56 , C04B35/5611 , C04B35/581 , C04B35/62222 , C04B41/009 , C04B41/4549 , C04B41/52 , C04B41/87 , C04B41/89 , C04B41/90 , C04B2111/00844 , C04B2235/3241 , C04B2235/3262 , C04B2235/3275 , C04B2235/3279 , C04B2235/3284 , C04B2235/3298 , C04B2235/79 , C04B2235/80 , C08K3/01 , C08K3/08 , C08K2201/011 , C08K2201/016 , G01N27/127 , H01C7/112 , H01C17/0652 , H01F1/0036 , H01F1/0045 , H01F1/36 , H01F41/0246 , H01G4/12 , H01G4/33 , H01L23/49883 , H01L2924/0002 , H01L2924/3011 , H01M4/02 , H01M4/04 , H01M4/242 , H01M4/581 , H01M4/5815 , H01M4/582 , H01M4/8875 , H01M4/8885 , H01M4/90 , H01M4/9066 , H01M8/1213 , H01M8/1246 , H01M8/1253 , H01M10/0562 , H01M10/0566 , Y02E60/324 , Y02E60/525 , Y02P70/56 , Y10S428/90 , Y10S977/762 , Y10S977/783 , Y10S977/81 , Y10S977/811 , Y10S977/948 , Y10T29/4902 , Y10T428/12056 , Y10T428/1216 , Y10T428/12181 , Y10T428/25 , Y10T428/254 , Y10T428/256 , Y10T428/257 , Y10T428/259 , Y10T428/2982 , Y10T428/2991 , Y10T428/2998 , B01J2523/33 , B01J2523/43 , B22F1/0018 , B22F2202/13 , B01J2523/31 , B01J2523/54 , B01J2523/67 , B01J2523/72 , B01J2523/845 , B01J2523/847 , B01J2523/22 , B01J2523/3706 , B01J2523/48 , B01J2523/18 , B01J2523/27 , B01J2523/824 , B01J2523/842 , B01J2523/17 , B01J2523/47 , B01J2523/56 , B01J2523/57 , C04B41/4539 , C04B41/5059 , C04B41/5116 , C04B41/5122 , C04B41/5027 , C04B41/5049 , C04B41/524 , C04B35/10 , B22F2201/11 , B01J2523/305 , B01J2523/69 , H01L2924/00
Abstract: Nanostructured non-stoichiometric non-equilibrium materials are disclosed. Novel electromagnetic materials and their applications are discussed. More specifically, the specifications teach the use of nanotechnology and nanostructured materials for developing novel electrical devices and products.
Abstract translation: 公开了纳米结构非化学计量非平衡材料。 讨论了新型电磁材料及其应用。 更具体地说,该规范教导了使用纳米技术和纳米结构材料来开发新的电子器件和产品。
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53.发明授权
公开(公告)号:US5984997A
公开(公告)日:1999-11-16
申请号:US46465
申请日:1998-03-23
Applicant: Clint Bickmore , Benjamin Galde , Tapesh Yadav , John Freim
Inventor: Clint Bickmore , Benjamin Galde , Tapesh Yadav , John Freim
CPC classification number: B82Y30/00 , B01J6/008 , C01B13/14 , C01G15/00 , C01G19/00 , C01G19/006 , C01G3/006 , C01G41/02 , C01G53/006 , C01P2002/32 , C01P2002/52 , C01P2002/54 , C01P2002/60 , C01P2002/72 , C01P2004/03 , C01P2004/16 , C01P2004/32 , C01P2004/62 , C01P2004/64 , C01P2006/12 , Y10S977/776 , Y10S977/777
Abstract: A process for producing nanoscale powders, and the powders so produced. The process comprises mixing an emulsion comprising all of the elements of the desired powder composition and a combustible fuel, and then combusting that emulsion to produce a powder. Powders with a median particle size of less than 50 nm have been made by this process. The process is suitable for the production of many types of powders, including particles and nanowhiskers of simple, doped, and polymetallic powders.
Abstract translation: 一种制备纳米级粉末的方法和如此制备的粉末。 该方法包括将包含所需粉末组合物的所有元素和可燃燃料的乳液混合,然后将该乳液燃烧以产生粉末。 通过该方法制备了中值粒径小于50nm的粉末。 该方法适用于生产许多类型的粉末,包括简单,掺杂和多金属粉末的颗粒和纳米晶须。
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公开(公告)号:US5788738A
公开(公告)日:1998-08-04
申请号:US707341
申请日:1996-09-03
Applicant: Shahid Pirzada , Tapesh Yadav
Inventor: Shahid Pirzada , Tapesh Yadav
IPC: B01J12/00 , B01J12/02 , B01J19/24 , B22F9/12 , C01B13/14 , C01B19/00 , C01B21/06 , C01B31/36 , C01B35/04 , C01F5/06 , C01F11/06 , C01F17/00 , C01G23/00 , C01G41/02 , C01G53/00 , C04B2/10
CPC classification number: B82Y30/00 , B01J12/005 , B01J12/02 , B01J19/088 , B01J19/24 , B22F9/12 , B82Y25/00 , B82Y5/00 , C01B13/145 , C01B19/007 , C01B21/062 , C01B31/36 , C01B35/04 , C01F11/06 , C01F17/0043 , C01F5/06 , C01G23/006 , C01G41/02 , C01G53/006 , C04B2/10 , B01J2219/00094 , B01J2219/00135 , B01J2219/00177 , B01J2219/0018 , B01J2219/0894 , B22F2999/00 , C01P2002/01 , C01P2002/02 , C01P2002/34 , C01P2002/60 , C01P2002/72 , C01P2004/03 , C01P2004/04 , C01P2004/38 , C01P2004/51 , C01P2004/54 , C01P2004/61 , C01P2004/62 , C01P2004/64 , C01P2006/10 , C01P2006/12 , C01P2006/40 , C01P2006/60
Abstract: A thermal reactor system that produces nanoscale powders by ultra-rapid thermal quench processing of high-temperature vapors through a boundary-layer converging-diverging nozzle. A gas suspension of precursor material is continuously fed to a thermal reaction chamber and vaporized under conditions that minimize superheating and favor nucleation of the resulting vapor. According to one aspect of the invention, the high temperature vapor is quenched using the principle of Joule-Thompson adiabatic expansion. Immediately after the initial nucleation stages, the vapor stream is passed through the nozzle and rapidly quenched through expansion at rates of at least 1,000.degree. C. per second, preferably greater than 1,000,000.degree. C. per second, to block the continued growth of the nucleated particles and produce a nanosize powder suspension of narrow particle-size distribution. According to another aspect of the invention, a gaseous boundary-layer stream is injected to form a blanket over the internal surface of the nozzle to prevent vapor condensation in the throat of the nozzle and its potential failure.
Abstract translation: 一种热反应器系统,通过边界层会聚发散喷嘴通过高温蒸气的超快速热淬火处理产生纳米级粉末。 将前体材料的气体悬浮液连续地供给到热反应室,并在使过热最小化并有利于所得蒸汽成核的条件下蒸发。 根据本发明的一个方面,使用焦耳汤普森绝热膨胀原理淬火高温蒸气。 在初始成核阶段之后,蒸气流通过喷嘴,并以每秒至少1000℃,优选大于1,000,000℃/秒的速率通过膨胀快速骤冷,以阻止有成核的 颗粒并产生窄粒度分布的纳米尺寸粉末悬浮液。 根据本发明的另一方面,喷射气体边界层流以在喷嘴的内表面上形成橡皮布,以防止喷嘴喉部中的蒸汽冷凝及其潜在的故障。
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55.发明授权公开(公告)号:US08263685B2
公开(公告)日:2012-09-11
申请号:US13050361
申请日:2011-03-17
Applicant: Tapesh Yadav
Inventor: Tapesh Yadav
IPC: C08K9/00 , C08K3/10 , G11B11/105
CPC classification number: C09C3/08 , B82Y30/00 , C01P2004/64 , C01P2006/22 , C09C1/3669 , C09C1/402 , C09C1/62 , C09C3/10 , C09D11/03 , C09D11/037 , Y10S977/786 , Y10T428/26
Abstract: Nanoparticle dispersions, inks, pastes, lotions and methods of their manufacture are disclosed. Multifunctional, nanocomposite, hollow nanoparticles, and coated nanoparticle dispersions are also discussed.
Abstract translation: 公开了纳米颗粒分散体,油墨,糊剂,洗剂及其制造方法。 还讨论了多功能纳米复合材料,中空纳米颗粒和涂覆的纳米颗粒分散体。
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Patent Agency Ranking
公开(公告)号:US20120164561A1
公开(公告)日:2012-06-28
申请号:US12121099
申请日:2008-05-15
Applicant: Tapesh Yadav
Inventor: Tapesh Yadav
CPC classification number: B82Y30/00 , H01M4/364 , H01M4/42 , H01M4/463 , H01M4/48 , H01M4/50 , H01M4/62 , H01M4/622 , H01M2004/021
Abstract: Nanoparticles comprising zinc, methods of manufacturing nanoparticles comprising zinc, and applications of nanoparticles comprising zinc, such as electrically conducting formulations, reagents for fine chemical synthesis, pigments and catalysts are provided, and more particularly, a coating, comprising a nanomaterial composition comprising zinc and at least one metal other than zinc, wherein the at least one metal comprises an element that (a) has an oxidation state higher than an oxidation state of zinc and that (b) dopes zinc in the nanomaterial composition, and wherein the coating has an electrical conductivity greater than 0.0001 mhos·cm.
Abstract translation: 提供了包含锌的纳米颗粒,制造包含锌的纳米颗粒的方法,以及包含锌的纳米颗粒的应用,例如导电制剂,用于精细化学合成的试剂,颜料和催化剂,更具体地,涉及一种包含纳米材料组合物的涂层,其包含锌和 至少一种不是锌的金属,其中所述至少一种金属包含(a)具有高于锌的氧化态的氧化态的元素和(b)所述纳米材料组合物中的掺杂锌,并且其中所述涂层具有 电导率大于0.0001 mhos·cm。
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公开(公告)号:US20110152427A1
公开(公告)日:2011-06-23
申请号:US13036851
申请日:2011-02-28
Applicant: Tapesh Yadav , Clayton Kostelecky , Evan Franke , Bijan Miremadi , Ming Au , Anthony Vigliotti
Inventor: Tapesh Yadav , Clayton Kostelecky , Evan Franke , Bijan Miremadi , Ming Au , Anthony Vigliotti
CPC classification number: B82Y30/00 , B82Y5/00 , B82Y25/00 , C01P2006/12 , C01P2006/40 , C08K3/01 , C08K3/08 , C08K2201/011 , H01F1/0063 , Y10T428/31504
Abstract: Methods for preparing nanocomposites with electrical properties modified by powder size below 100 nanometers. Both low-loaded and highly-loaded nanocomposites are included. Nanoscale coated, un-coated, whisker type fillers are taught. Electrical nanocomposite layers may be prepared on substrates.
Abstract translation: 制备具有由粉末尺寸低于100纳米改性的电学性质的纳米复合材料的方法。 包括低负载和高负载的纳米复合材料。 教导了纳米级涂层,未涂覆的晶须型填料。 可以在基底上制备电纳米复合层。
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公开(公告)号:US07857244B2
公开(公告)日:2010-12-28
申请号:US11641048
申请日:2006-12-19
Applicant: Tapesh Yadav , Karl Pfaffenbach
Inventor: Tapesh Yadav , Karl Pfaffenbach
IPC: B02C19/00
CPC classification number: H01G4/12 , A62C31/03 , B01J12/005 , B01J12/02 , B01J19/24 , B01J2219/00094 , B01J2219/00135 , B01J2219/00155 , B01J2219/00177 , B01J2219/0018 , B01J2219/0894 , B05B1/12 , B22F1/0003 , B22F9/12 , B22F2999/00 , B29C70/58 , B32B2309/022 , B82B1/00 , B82Y30/00 , C01B13/145 , C01B19/007 , C01B21/062 , C01B32/956 , C01B35/04 , C01F5/06 , C01F11/06 , C01F17/0043 , C01G23/006 , C01G41/02 , C01G53/006 , C01P2002/72 , C01P2004/03 , C01P2004/04 , C01P2004/51 , C01P2004/54 , C01P2004/64 , C01P2006/12 , C01P2006/40 , C01P2006/80 , C04B2/10 , C04B20/0004 , C04B35/565 , C04B35/62222 , C04B35/638 , C04B41/52 , C04B41/89 , C04B2235/6025 , C08K3/01 , C08K3/08 , C08K2201/011 , C08K2201/016 , C09C3/006 , C09C3/04 , H01C7/112 , H01C17/06513 , H01G4/33 , H01M4/9066 , H01M8/1213 , H01M8/1246 , H01M8/1253 , Y02E60/525 , Y02P70/56 , Y10S977/84 , Y10S977/90 , B22F1/0018 , B22F2202/13
Abstract: Methods for preparing high aspect ratio nanomaterials from spherical nanomaterials useful for oxides, nitrides, carbides, borides, metals, alloys, chalcogenides, and other compositions.
Abstract translation: 用于氧化物,氮化物,碳化物,硼化物,金属,合金,硫属化物和其它组合物的球形纳米材料制备高纵横比纳米材料的方法。
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公开(公告)号:US20100320417A1
公开(公告)日:2010-12-23
申请号:US12081115
申请日:2008-04-10
Applicant: Tapesh Yadav , Clayton Kostelecky , Evan Franke , Bijan Miremadi , Ming Au , Anthony Vigliotti
Inventor: Tapesh Yadav , Clayton Kostelecky , Evan Franke , Bijan Miremadi , Ming Au , Anthony Vigliotti
IPC: C09K3/00
CPC classification number: C04B20/0004 , B01J12/005 , B01J12/02 , B01J19/24 , B01J2219/00094 , B01J2219/00135 , B01J2219/00155 , B01J2219/00177 , B01J2219/0018 , B01J2219/0894 , B05B1/12 , B22F1/0003 , B22F1/0018 , B22F1/0044 , B22F1/02 , B22F9/12 , B22F2999/00 , B29C70/58 , B82B1/00 , B82Y20/00 , B82Y25/00 , B82Y30/00 , C01B13/145 , C01B13/363 , C01B19/007 , C01B21/062 , C01B25/08 , C01B32/90 , C01B32/914 , C01B32/956 , C01B35/04 , C01F5/06 , C01F11/06 , C01F17/0043 , C01G15/00 , C01G19/00 , C01G19/006 , C01G19/02 , C01G23/006 , C01G41/02 , C01G49/0018 , C01G49/0063 , C01G53/006 , C01P2002/01 , C01P2002/02 , C01P2002/34 , C01P2002/52 , C01P2002/54 , C01P2002/60 , C01P2002/72 , C01P2004/03 , C01P2004/04 , C01P2004/10 , C01P2004/16 , C01P2004/20 , C01P2004/38 , C01P2004/51 , C01P2004/52 , C01P2004/54 , C01P2004/61 , C01P2004/62 , C01P2004/64 , C01P2004/84 , C01P2004/86 , C01P2006/10 , C01P2006/12 , C01P2006/42 , C04B2/10 , C04B20/1018 , C04B20/1029 , C04B26/02 , C04B26/06 , C04B35/01 , C04B35/265 , C04B35/453 , C04B35/457 , C04B35/547 , C04B35/62222 , C04B35/6265 , C04B35/628 , C04B35/63456 , C04B35/653 , C04B41/009 , C04B41/52 , C04B41/89 , C04B41/90 , C04B2111/00008 , C04B2111/00482 , C04B2111/00844 , C04B2235/3201 , C04B2235/3206 , C04B2235/3241 , C04B2235/3262 , C04B2235/3275 , C04B2235/3279 , C04B2235/3284 , C04B2235/3286 , C04B2235/3298 , C04B2235/3418 , C04B2235/444 , C04B2235/5409 , C04B2235/5454 , C04B2235/549 , C04B2235/6562 , C04B2235/6565 , C08K3/01 , C08K3/013 , C08K3/08 , C08K9/02 , C08K2201/011 , C09C1/00 , C09C1/0081 , C09C1/22 , C09C1/627 , C09C3/08 , C09C3/10 , H01B1/22 , H01C7/105 , H01C7/112 , H01F1/0063 , H01F1/344 , H01F1/36 , H01G4/12 , H01G4/33 , H01M4/5815 , H01M4/9066 , H01M6/20 , H01M6/36 , H01M8/1213 , H01M8/1246 , H01M8/1253 , H01M2004/021 , Y02E60/525 , Y02P40/42 , Y02P70/56 , Y10S977/70 , Y10T428/2998 , Y10T428/31663 , B22F2202/13 , B22F1/0059 , C04B14/30 , C04B20/008 , C04B24/2623 , C04B14/322 , C04B14/325 , C04B14/38 , C04B2103/40 , C04B2103/408 , C04B35/10 , C04B41/4539 , C04B41/5116 , C04B41/5122 , C04B41/4549 , C04B41/5027 , C04B41/5049
Abstract: Methods for preparing nanocomposites with thermal properties modified by powder size below 100 nanometers. Both low-loaded and highly-loaded nanocomposites are included. Nanoscale coated, un-coated, whisker type fillers are taught. Thermal nanocomposite layers may be prepared on substrates.
Abstract translation: 制备具有由粉末尺寸低于100纳米改性的热性能的纳米复合材料的方法。 包括低负载和高负载的纳米复合材料。 教导了纳米级涂层,未涂覆的晶须型填料。 可以在基底上制备热纳米复合层。
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公开(公告)号:US20100279106A1
公开(公告)日:2010-11-04
申请号:US12000310
申请日:2007-12-11
Applicant: Tapesh Yadav , Hongxing Hu
Inventor: Tapesh Yadav , Hongxing Hu
CPC classification number: B82Y30/00 , B01J12/005 , B01J12/02 , B01J19/24 , B01J2219/00094 , B01J2219/00135 , B01J2219/00155 , B01J2219/00177 , B01J2219/0018 , B01J2219/0894 , B22F1/0003 , B22F9/12 , B22F2999/00 , B29C70/58 , B82B1/00 , B82Y5/00 , B82Y25/00 , C01B13/145 , C01B19/007 , C01B21/062 , C01B32/956 , C01B35/04 , C01F5/06 , C01F11/06 , C01F17/0043 , C01G23/006 , C01G41/02 , C01P2002/01 , C01P2002/02 , C01P2002/34 , C01P2002/54 , C01P2002/60 , C01P2002/72 , C01P2004/03 , C01P2004/04 , C01P2004/38 , C01P2004/51 , C01P2004/54 , C01P2004/61 , C01P2004/62 , C01P2004/64 , C01P2004/82 , C01P2006/10 , C01P2006/12 , C01P2006/40 , C01P2006/60 , C01P2006/80 , C04B2/10 , C04B35/62222 , C04B41/52 , C04B41/89 , C08J5/005 , C08K3/01 , C08K3/08 , C08K2201/011 , H01C7/112 , H01F1/0063 , H01G4/12 , H01G4/33 , H01M4/9066 , H01M8/1213 , H01M8/1246 , H01M8/1253 , Y02E60/525 , Y02P40/42 , Y02P70/56 , Y10S977/89 , Y10T29/49002 , Y10T29/49082 , Y10T428/26 , B22F2202/13 , B22F1/0018
Abstract: Electronic devices prepared from nanoscale powders are described. Methods for utilizing nanoscale powders and related nanotechnology to prepare capacitors, inductors, resistors, thermistors, varistors, filters, arrays, interconnects, optical components, batteries, fuel cells, sensors and other products are discussed.
Abstract translation: 描述了由纳米级粉末制备的电子器件。 讨论了利用纳米级粉末和相关纳米技术制备电容器,电感器,电阻器,热敏电阻器,变阻器,滤波器,阵列,互连,光学部件,电池,燃料电池,传感器和其他产品的方法。
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