1
Tapesh Yadav, Clayton Kostelecky, Evan Franke, Bijan Miremadi, Ming Au: Nanostructured fillers and carriers. Nanomaterials Research Corporation, Sam Pasternack Esq, Stuart T Langley Esq, May 8, 2001: US06228904 (229 worldwide citation)

A nanocomposite structure comprising a nanostructured filler or carrier intimately mixed with a matrix, and methods of making such a structure. The nanostructured filler has a domain size sufficiently small to alter an electrical, magnetic, optical, electrochemical, chemical, thermal, biomedical, or ...


2
Tapesh Yadav, Clayton Kostelecky: Non-spherical nanopowder derived nanocomposites. NanoProducts Corporation, Stuart T Langley, Hogan & Hartson, July 12, 2005: US06916872 (115 worldwide citation)

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 applica ...


3
Tapesh Yadav, Clayton Kostelecky: Nanotechnology for drug delivery, contrast agents and biomedical implants. NanoProducts Corporation, Stuart T Langley, Hogan & Hartson L, August 23, 2005: US06933331 (98 worldwide citation)

A nanocomposite structure comprising a nanostructured filler or carrier intimately mixed with a matrix, and methods of making such a structure. The nanostructured filler has a domain size sufficiently small to alter an electrical, magnetic, optical, electrochemical, chemical, thermal, biomedical, or ...


4
Anthony Vigliotti, Tapesh Yadav, Clayton Kostelecky, Carrie Wyse: Reducing manufacturing and raw material costs for device manufacture with nanostructured powders. NanoProducts Corporation, Stuart T Langley, Hogan & Hartson, November 4, 2003: US06641775 (97 worldwide citation)

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.


5
Tapesh Yadav, Clayton Kostelecky: Polymer nanocomposite implants with enhanced transparency and mechanical properties for administration within humans or animals. NanoProducts Corporation, Stuart T Langley Esq, Hogan & Hartson L, February 15, 2005: US06855749 (79 worldwide citation)

Polymer nanocomposite implants with nanofillers and additives are described. The nanofillers described can be any composition with the preferred composition being those composing barium, bismuth, cerium, dysprosium, europium, gadolinium, hafnium, indium, lanthanum, neodymium, niobium, praseodymium, ...


6
Anthony Vigliotti, Tapesh Yadav, Clayton Kostelecky, Carrie Wyse: Thermal sensors prepared from nanostructureed powders. NanoProducts Corporation, Stuart T Langley, Hogan & Hartson, February 4, 2003: US06514453 (28 worldwide citation)

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 th ...


7
Tapesh Yadav, Clayton Kostelecky, Evan Franke, Bijan Miremadi, Ming Au, Anthony Vigliotti: Nanomaterials and magnetic media with coated nanostructured fillers and carriers. NanoProducts Corporation, Stuart T Langley, Hogan & Hartson, May 18, 2004: US06737463 (17 worldwide citation)

Coated nanoparticles are used for composites and media. Exemplary applications include magnetic applications involving a solid matrix material and a nanostructured magnetic material.


8
Tapesh Yadav, Clayton Kostelecky: Non-stoichiometric nanomaterial compositions with distinctive shape and morphology. PPG Industries Ohio, October 19, 2010: US07816006 (5 worldwide citation)

Nanoscale materials with domain sizes less than 100 nanometers and unusual shapes and morphologies are disclosed. A broad approach for manufacturing oxide and non-oxide nanomaterials with aspect ratio different than 1.0 is presented. Methods for engineering and manufacturing nanomaterials' size, sha ...


9
Tapesh Yadav, Clayton Kostelecky: Conductive nanocomposite films. NanoProducts Corporation, Foley & Lardner, July 31, 2007: US07250454 (4 worldwide citation)

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-co ...


10
Tapesh Yadav, Clayton Kostelecky: Conductive nanocomposite films. PPG Industries Ohio, Donald R Palladino, William Kuss, November 15, 2011: US08058337 (2 worldwide citation)

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-co ...



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