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公开(公告)号:US20070102294A1
公开(公告)日:2007-05-10
申请号:US11533729
申请日:2006-09-20
IPC分类号: G01N27/26
CPC分类号: G01N27/4074 , G01N27/4071 , G01N33/004 , G01N33/0044 , G01N33/0047
摘要: An electrochemical gas sensor, a method for making the sensor and methods for the detection of a gaseous species. The electrochemical gas sensor is a solid-state gas sensor that includes a solid polymer electrolyte. A working electrode is separated from a counter electrode by the solid polymer electrolyte. The sensor can include a multilaminate structure for improved detection properties, where electrode microbands are disposed within the solid polymer electrolyte.
摘要翻译: 电化学气体传感器,制造传感器的方法和检测气态物质的方法。 电化学气体传感器是固体气体传感器,其包括固体聚合物电解质。 通过固体聚合物电解质将工作电极与对电极分离。 传感器可以包括用于改善检测特性的多层结构,其中电极微带设置在固体聚合物电解质内。
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公开(公告)号:US06916872B2
公开(公告)日:2005-07-12
申请号:US10449282
申请日:2003-05-30
申请人: Tapesh Yadav , Clayton Kostelecky
发明人: Tapesh Yadav , Clayton Kostelecky
IPC分类号: A61K9/51 , A62C31/03 , B01J12/00 , B01J12/02 , B01J19/24 , B05B1/12 , B22F1/00 , B22F9/12 , B29C70/58 , B82B1/00 , C01B13/14 , C01B19/00 , C01B21/06 , C01B31/36 , C01B35/04 , C01F5/06 , C01F11/06 , C01F17/00 , C01G19/00 , C01G23/00 , C01G41/02 , C01G49/00 , C01G53/00 , C04B2/10 , C04B20/00 , C04B35/622 , C04B41/52 , C04B41/89 , C08K3/00 , C08K3/08 , G01N27/12 , G01N27/30 , G01N33/00 , H01C7/112 , H01G4/12 , H01G4/33 , H01M4/02 , H01M4/58 , H01M6/36 , H01M8/12 , C08K3/18
CPC分类号: 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
摘要: Nanocomposites from nanofillers with preferred form of whiskers, rods, plates and fibers are disclosed. The matrix composition described includes polymers, ceramics and metals. The composition disclosed include inorganic, organic and metallic. These nanocomposites are useful in wide range of applications given their unusual properties such as refractive index, transparency to light, reflection characteristics, resistivity, permittivity, permeability, coercivity, B-H product, magnetic hysteresis, breakdown voltage, skin depth, curie temperature, dissipation factor, work function, band gap, electromagnetic shielding effectiveness, radiation hardness, chemical reactivity, thermal conductivity, temperature coefficient of an electrical property, voltage coefficient of an electrical property, thermal shock resistance, biocompatibility, and wear rate.
摘要翻译: 公开了具有优选形式的晶须,棒,板和纤维的纳米填料的纳米复合材料。 所述的基体组合物包括聚合物,陶瓷和金属。 所公开的组合物包括无机,有机和金属。 这些纳米复合材料在广泛的应用中是有用的,因为它们的不寻常的性质如折射率,透明度,光反射特性,电阻率,介电常数,磁导率,矫顽力,BH产物,磁滞,击穿电压,皮肤深度,居里温度,损耗因子 工作功能,带隙,电磁屏蔽效能,辐射硬度,化学反应性,导热性,电性能的温度系数,电性能的电压系数,耐热冲击性,生物相容性和磨损率。
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3.发明授权公开(公告)号:US06641775B2
公开(公告)日:2003-11-04
申请号:US10001660
申请日:2001-12-03
IPC分类号: C04B3332
CPC分类号: B82Y30/00 , C04B35/01 , Y10S977/775 , Y10S977/833 , Y10S977/84 , Y10S977/955 , Y10T29/49085 , Y10T428/29
摘要: Methods for lowering processing and raw material costs are disclosed. Specifically, the use of nanostructured powders is disclosed for faster and lower sintering temperatures whereby electrodes currently employing platinum can be substituted with lower melting point metals and alloys.
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公开(公告)号:US08389603B2
公开(公告)日:2013-03-05
申请号:US10435222
申请日:2003-05-09
申请人: Tapesh Yadav , Clayton Kostelecky , Evan Franke , Bijan Miremadi , Ming Au , Anthony Vigliotti
发明人: Tapesh Yadav , Clayton Kostelecky , Evan Franke , Bijan Miremadi , Ming Au , Anthony Vigliotti
IPC分类号: C08K9/04 , C08K9/10 , C08K3/10 , C08K3/14 , C08K3/28 , C08K3/30 , C08K3/32 , C08K3/34 , C08K3/38
CPC分类号: 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
摘要: 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.
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公开(公告)号:US08058337B2
公开(公告)日:2011-11-15
申请号:US11808766
申请日:2007-06-12
申请人: Tapesh Yadav , Clayton Kostelecky
发明人: Tapesh Yadav , Clayton Kostelecky
CPC分类号: 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
摘要: Methods for preparing low resistivity nanocomposite layers that simultaneously offer optical clarity, wear resistance and superior functional performance. Nanofillers and a substance having a polymer are mixed. Both low-loaded and highly-loaded nanocomposites are included. Nanoscale coated and un-coated fillers may be used. Nanocomposite films may be coated on substrates.
摘要翻译: 制备低电阻率纳米复合层的方法,同时提供光学透明度,耐磨性和优异的功能性能。 纳米填料和具有聚合物的物质混合。 包括低负载和高负载的纳米复合材料。 可以使用纳米涂层和未涂覆的填料。 纳米复合膜可以涂覆在基材上。
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公开(公告)号:US07238734B2
公开(公告)日:2007-07-03
申请号:US10435287
申请日:2003-05-09
申请人: Tapesh Yadav , Clayton Kostelecky
发明人: Tapesh Yadav , Clayton Kostelecky
CPC分类号: 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
摘要: Methods for preparing optical filter nanocomposites from nanopowders. Both low-loaded and highly-loaded nanocomposites are included. Nanoscale coated and un-coated fillers may be used. Nanocomposite filter layers may be prepared on substrates. Gradient nanocomposites for filters are discussed.
摘要翻译: 从纳米粉末制备滤光片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。 可以使用纳米涂层和未涂覆的填料。 纳米复合过滤层可以在基材上制备。 讨论了过滤器的梯度纳米复合材料。
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公开(公告)号:US07183337B1
公开(公告)日:2007-02-27
申请号:US10426414
申请日:2003-04-30
申请人: Tapesh Yadav , Clayton Kostelecky
发明人: Tapesh Yadav , Clayton Kostelecky
CPC分类号: 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
摘要: Methods for preparing nanocomposites that enable films with optical clarity, wear resistance and superior functional performance. Nanofillers and a substance having a polymer are mixed. Both low-loaded and highly-loaded nanocomposites are included. Nanocomposite films may be coated on substrates.
摘要翻译: 制备具有光学透明度,耐磨性和优异功能性能的纳米复合材料的方法。 纳米填料和具有聚合物的物质混合。 包括低负载和高负载的纳米复合材料。 纳米复合膜可以涂覆在基材上。
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公开(公告)号:US06514453B2
公开(公告)日:2003-02-04
申请号:US09024837
申请日:1998-02-17
IPC分类号: C04B3332
CPC分类号: B82Y30/00 , C04B35/01 , Y10S977/775 , Y10S977/833 , Y10S977/84 , Y10S977/955 , Y10T29/49085 , Y10T428/29
摘要: This invention describes a method of rapidly monitoring the temperature of a medium and a method of preparing a quantum confined device that can enable such measurements. The monitoring principle uses changes in impedance of nanostructured devices, i.e. devices in which one or more materials have the domain size precision engineered to less than 500 nanometers, preferably to dimensions less than the domain sizes where quantum confinement effects become significant and modify the electrical or thermal properties of the materials. The invention can be used to monitor absolute values of and changes in temperature of gases, inorganic and organic liquids, solids, suspensions, and mixtures of one or more of the said phases. The invention can be used to monitor radiation, power, heat and mass flow, charge and momentum flow, and phase transformation.
摘要翻译: 本发明描述了一种快速监测介质温度的方法和一种制备可实现这种测量的量子限制装置的方法。 监测原理使用纳米结构器件的阻抗变化,即其中一种或多种材料的结构域尺寸精确设计为小于500纳米的器件,优选地尺寸小于量子限制效应变得显着的畴尺寸,并修改电或 材料的热性能。 本发明可用于监测气体,无机和有机液体,固体,悬浮液和一个或多个所述相的混合物的绝对值和温度变化。 本发明可用于监测辐射,功率,热和质量流量,电荷和动量流量以及相变。
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公开(公告)号:US08501267B2
公开(公告)日:2013-08-06
申请号:US13036851
申请日:2011-02-28
申请人: Tapesh Yadav , Clayton Kostelecky , Evan Franke , Bijan Miremadi , Ming Au , Anthony Vigliotti
发明人: Tapesh Yadav , Clayton Kostelecky , Evan Franke , Bijan Miremadi , Ming Au , Anthony Vigliotti
CPC分类号: B82Y30/00 , B82Y5/00 , B82Y25/00 , C01P2006/12 , C01P2006/40 , C08K3/01 , C08K3/08 , C08K2201/011 , H01F1/0063 , Y10T428/31504
摘要: 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.
摘要翻译: 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:US07387673B2
公开(公告)日:2008-06-17
申请号:US10441501
申请日:2003-05-20
申请人: Tapesh Yadav , Clayton Kostelecky
发明人: Tapesh Yadav , Clayton Kostelecky
CPC分类号: 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
摘要: A pigment prepared using nanofillers with modified properties because of the powder size being below 100 nanometers. Blue, yellow and brown pigments are illustrated. Nanoscale coated, un-coated, nanorods type fillers are included. The pigment nanopowders taught comprise one or more elements from the group actinium, antimony, aluminum, arsenic, barium, beryllium, bismuth, cadmium, calcium, cerium, cesium, cobalt, copper, dysprosium, erbium, europium, gadolinium, gallium, gold, hafnium, hydrogen, indium, iridium, iron, lanthanum, lithium, magnesium, manganese, mendelevium, mercury, molybdenum, neodymium, neptunium, nickel, niobium, nitrogen, oxygen, osmium, palladium, platinum, potassium, praseodymium, promethium, protactinium, rhenium, rubidium, scandium, silver, sodium, strontium, sulfur, selenium, tantalum, terbium, thallium, thorium, tin, titanium, tungsten, vanadium, ytterbium, yttrium, zinc, and zirconium.
摘要翻译: 由于粉末尺寸低于100纳米,使用具有改性特性的纳米填料制备的颜料。 蓝色,黄色和棕色颜料。 包括纳米涂层,未涂覆的纳米棒型填料。 教导的颜料纳米粉体包括一组或多种来自锕,锑,铝,砷,钡,铍,铋,镉,钙,铈,铯,钴,铜,镝,铒,铕,钆,镓, 铪,氢,铟,铱,铁,镧,锂,镁,锰,锑,汞,钼,钕,ium,镍,铌,氮,氧,锇,钯,铂,钾,镨,prom,prot, 铼,铷,钪,银,钠,锶,硫,硒,钽,铽,铊,钍,锡,钛,钨,钒,镱,钇,锌和锆。
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