Patents by Inventor David R. Wheeler
David R. Wheeler has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Patent number: 9291508Abstract: An atomic interferometric device useful, e.g., for measuring acceleration or rotation is provided. The device comprises at least one vapor cell containing a Raman-active chemical species, an optical system, and at least one detector. The optical system is conformed to implement a Raman pulse interferometer in which Raman transitions are stimulated in a warm vapor of the Raman-active chemical species. The detector is conformed to detect changes in the populations of different internal states of atoms that have been irradiated by the optical system.Type: GrantFiled: March 13, 2014Date of Patent: March 22, 2016Assignee: Sandia CorporationInventors: Grant Biedermann, Hayden James Evans McGuinness, Akash Rakholia, Yuan-Yu Jau, Peter Schwindt, David R. Wheeler
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Patent number: 9212430Abstract: A method for preparing an electrochemical biosensor uses bias-assisted assembly of unreactive -onium molecules on an electrode array followed by post-assembly electro-addressable conversion of the unreactive group to a chemical or biological recognition group. Electro-addressable functionalization of electrode arrays enables the multi-target electrochemical sensing of biological and chemical analytes.Type: GrantFiled: October 31, 2007Date of Patent: December 15, 2015Assignee: Sandia CorporationInventors: Jason C. Harper, Ronen Polsky, Shawn M. Dirk, David R. Wheeler, Dulce C. Arango, Susan M. Brozik
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Patent number: 9157161Abstract: A thin film with multiple binding functionality can be prepared on an electrode surface via consecutive electroreduction of two or more aryl-onium salts with different functional groups. This versatile and simple method for forming multifunctional surfaces provides an effective means for immobilization of diverse molecules at close proximities. The multifunctional thin film has applications in bioelectronics, molecular electronics, clinical diagnostics, and chemical and biological sensing.Type: GrantFiled: July 14, 2011Date of Patent: October 13, 2015Assignee: Sandia CorporationInventors: Susan M. Brozik, Jason C. Harper, Ronen Polsky, David R. Wheeler, Dulce C. Arango, Shawn M. Dirk
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Publication number: 20150267316Abstract: A purification method that uses ion-selective ceramics to electrochemically filter waste products from a molten salt. The electrochemical method uses ion-conducting ceramics that are selective for the molten salt cations desired in the final purified melt, and selective against any contaminant ions. The method can be integrated into a slightly modified version of the electrochemical framework currently used in pyroprocessing of nuclear wastes.Type: ApplicationFiled: March 17, 2015Publication date: September 24, 2015Inventors: Erik David Spoerke, Jon Ihlefeld, Karen Waldrip, Jill S. Wheeler, Harlan James Brown-Shaklee, Leo J. Small, David R. Wheeler
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Patent number: 9102801Abstract: A method including reducing a particle size of lignin particles to an average particle size less than 40 nanometers; after reducing the particle size, combining the lignin particles with a polymeric material; and forming a structure of the combination. A method including exposing lignin to a diazonium precursor including a functional group; modifying the lignin by introducing the functional group to the lignin; and combining the modified lignin with a polymeric material to form a composite. An apparatus including a composite of a polymer and lignin wherein the lignin has an average particle size less than 100 micrometers.Type: GrantFiled: August 29, 2012Date of Patent: August 11, 2015Assignees: Sandia Corporation, The Goodyear Tire & Rubber CompanyInventors: Shawn M. Dirk, Kirsten Nicole Cicotte, David R. Wheeler, David A. Benko
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Publication number: 20150148436Abstract: A pressure-based chemical etch method is used to shape polymer nanopores into cones. By varying the pressure, the pore tip diameter can be controlled, while the pore base diameter is largely unaffected. The method provides an easy, low-cost approach for conically etching high density nanopores.Type: ApplicationFiled: November 17, 2014Publication date: May 28, 2015Inventors: Leo J. Small, Erik David Spoerke, David R. Wheeler
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Patent number: 8859190Abstract: Novel photo-writable and thermally switchable polymeric materials exhibit a refractive index change of ?n?1.0 when exposed to UV light or heat. For example, lithography can be used to convert a non-conjugated precursor polymer to a conjugated polymer having a higher index-of-refraction. Further, two-photon lithography can be used to pattern high-spatial frequency structures.Type: GrantFiled: September 4, 2013Date of Patent: October 14, 2014Assignee: Sandia CorporationInventors: Shawn M. Dirk, Ross Stefan Johnson, Robert Boye, Michael R. Descour, William C. Sweatt, David R. Wheeler, Bryan James Kaehr
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Patent number: 8736000Abstract: A microfabricated capacitive chemical sensor can be used as an autonomous chemical sensor or as an analyte-sensitive chemical preconcentrator in a larger microanalytical system. The capacitive chemical sensor detects changes in sensing film dielectric properties, such as the dielectric constant, conductivity, or dimensionality. These changes result from the interaction of a target analyte with the sensing film. This capability provides a low-power, self-heating chemical sensor suitable for remote and unattended sensing applications. The capacitive chemical sensor also enables a smart, analyte-sensitive chemical preconcentrator. After sorption of the sample by the sensing film, the film can be rapidly heated to release the sample for further analysis. Therefore, the capacitive chemical sensor can optimize the sample collection time prior to release to enable the rapid and accurate analysis of analytes by a microanalytical system.Type: GrantFiled: October 19, 2006Date of Patent: May 27, 2014Assignee: Sandia CorporationInventors: Ronald P. Manginell, Matthew W. Moorman, David R. Wheeler
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Patent number: 8426321Abstract: A process for making a dielectric material where a precursor polymer selected from poly(phenylene vinylene)polyacetylene, poly(p-phenylene), poly(thienylene vinylene), poly(1,4-naphthylene vinylene), and poly(p-pyridine vinylene) is energized said by exposure by radiation or increase in temperature to a level sufficient to eliminate said leaving groups contained within the precursor polymer, thereby transforming the dielectric material into a conductive polymer. The leaving group in the precursor polymer can be a chloride, a bromide, an iodide, a fluoride, an ester, an xanthate, a nitrile, an amine, a nitro group, a carbonate, a dithiocarbamate, a sulfonium group, an oxonium group, an iodonium group, a pyridinium group, an ammonium group, a borate group, a borane group, a sulphinyl group, or a sulfonyl group.Type: GrantFiled: May 2, 2011Date of Patent: April 23, 2013Assignee: Sandia CorporationInventors: Shawn M. Dirk, Ross S. Johnson, David R. Wheeler, Gregory R. Bogart
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Patent number: 8349547Abstract: A lithographic method is used to fabricate porous carbon structures that can provide electrochemical electrodes having high surface area with uniform and controllable dimensions, providing enormous flexibility to tailor the electrodes toward specific applications. Metal nanoparticles deposited on the surface of the porous carbon electrodes exhibit ultra small dimensions with uniform size distribution. The resulting electrodes are rugged, electrically conductive and show excellent electrochemical behavior.Type: GrantFiled: September 2, 2010Date of Patent: January 8, 2013Assignee: Sandia CorporationInventors: David Bruce Burckel, Cody M. Washburn, Ronen Polsky, Susan M. Brozik, David R. Wheeler
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Patent number: 8298488Abstract: A microfabricated TID comprises a microhotplate and a thermionic source disposed on the microhotplate. The microfabricated TID can provide high sensitivity and selectivity to nitrogen- and phosphorous-containing compounds and other compounds containing electronegative function groups. The microfabricated TID can be microfabricated with semiconductor-based materials. The microfabricated TID can be combined with a microfabricated separation column and used in microanalytical system for the rapid on-site detection of pesticides, chemical warfare agents, explosives, pharmaceuticals, and other organic compounds that contain nitrogen or phosphorus.Type: GrantFiled: November 4, 2004Date of Patent: October 30, 2012Assignee: Sandia CorporationInventors: Patrick R. Lewis, Ronald P. Manginell, David R. Wheeler, Daniel E. Trudell
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Patent number: 8223472Abstract: A capacitor having at least one electrode pair being separated by a dielectric component, with the dielectric component being made of a polymer such as a norbornylene-containing polymer with a dielectric constant greater than 3 and a dissipation factor less than 0.1 where the capacitor has an operating temperature greater than 100° C. and less than 170° C.Type: GrantFiled: November 14, 2008Date of Patent: July 17, 2012Assignee: Sandia CorporationInventors: Shawn M. Dirk, David R. Wheeler
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Patent number: 7955945Abstract: A process for making a dielectric material where a precursor polymer selected from poly(phenylene vinylene) polyacetylene, poly(p-phenylene), poly(thienylene vinylene), poly(1,4-naphthylene vinylene), and poly(p-pyridine vinylene) is energized said by exposure by radiation or increase in temperature to a level sufficient to eliminate said leaving groups contained within the precursor polymer, thereby transforming the dielectric material into a conductive polymer. The leaving group in the precursor polymer can be a chloride, a bromide, an iodide, a fluoride, an ester, an xanthate, a nitrile, an amine, a nitro group, a carbonate, a dithiocarbamate, a sulfonium group, an oxonium group, an iodonium group, a pyridinium group, an ammonium group, a borate group, a borane group, a sulphinyl group, or a sulfonyl group.Type: GrantFiled: September 28, 2010Date of Patent: June 7, 2011Assignee: Sandia CorporationInventors: Shawn M. Dirk, Ross S. Johnson, David R. Wheeler, Gregory R. Bogart
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Patent number: 7799280Abstract: A non-planar, tortuous path chemical preconcentrator has a high internal surface area having a heatable sorptive coating that can be used to selectively collect and concentrate one or more chemical species of interest from a fluid stream that can be rapidly released as a concentrated plug into an analytical or microanalytical chain for separation and detection. The non-planar chemical preconcentrator comprises a sorptive support structure having a tortuous flow path. The tortuosity provides repeated twists, turns, and bends to the flow, thereby increasing the interfacial contact between sample fluid stream and the sorptive material. The tortuous path also provides more opportunities for desorption and readsorption of volatile species. Further, the thermal efficiency of the tortuous path chemical preconcentrator is comparable or superior to the prior non-planar chemical preconcentrator.Type: GrantFiled: February 16, 2006Date of Patent: September 21, 2010Assignee: Sandia CorporationInventors: Ronald P. Manginell, Patrick R. Lewis, Douglas R. Adkins, David R. Wheeler, Robert J. Simonson
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Patent number: 7622596Abstract: Two new surfactant molecules are reported which contain thermally labile Diels-Alder adducts connecting the polar and non-polar sections of each molecule. The two surfactants possess identical non-polar dodecyl tail segments but exhibit different polar headgroups. The surfactants become soluble in water when anionic salts are formed through the deprotonation of the surfactant headgroups by the addition of potassium hydroxide. When either surfactant is exposed to temperature above about 60° C., the retro Diels-Alder reaction occurs, yielding hydrophilic and hydrophobic fragments or the aqueous solutions of the surfactants subsequently exhibit loss of all surface-active behavior.Type: GrantFiled: March 29, 2006Date of Patent: November 24, 2009Assignee: Sandia CorporationInventors: James R. McElhanon, Blake A. Simmons, Thomas Zifer, Gregory M. Jamison, Douglas A. Loy, Kamyar Rahimian, Timothy M. Long, David R. Wheeler, Chad L. Staiger
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Patent number: 7595349Abstract: Two new surfactant molecules are reported which contain thermally labile Diels-Alder adducts connecting the polar and non-polar sections of each molecule. The two surfactants possess identical non-polar dodecyl tail segments but exhibit different polar headgroups. The surfactants become soluble in water when anionic salts are formed through the deprotonation of the surfactant headgroups by the addition of potassium hydroxide. When either surfactant is exposed to temperature above about 60° C., the retro Diels-Alder reaction occurs, yielding hydrophilic and hydrophobic fragments or the aqueous solutions of the surfactants subsequently exhibit loss of all surface-active behavior.Type: GrantFiled: January 26, 2006Date of Patent: September 29, 2009Assignee: Sandia CorporationInventors: James R. McElhanon, Blake A. Simmons, Thomas Zifer, Gregory M. Jamison, Douglas A. Loy, Kamyar Rahimian, Timothy M. Long, David R. Wheeler, Chad L. Staiger
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Patent number: 7550071Abstract: Methods are described for the electrochemical assembly of organic molecules on silicon, or other conducting or semiconducting substrates, using iodonium salt precursors. Iodonium molecules do not assemble on conducting surfaces without a negative bias. Accordingly, the iodonium salts are preferred for patterning applications that rely on direct writing with negative bias. The stability of the iodonium molecule to acidic conditions allows them to be used with standard silicon processing. As a directed assembly process, the use of iodonium salts provides for small features while maintaining the ability to work on a surface and create structures on a wafer level. Therefore, the process is amenable for mass production. Furthermore, the assembled monolayer (or multilayer) is chemically robust, allowing for subsequent chemical manipulations and the introduction of various molecular functionalities for various chemical and biological applications.Type: GrantFiled: February 25, 2005Date of Patent: June 23, 2009Assignee: Sandia CorporationInventors: Shawn M. Dirk, Stephen W. Howell, David R. Wheeler
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Patent number: 7378533Abstract: The present invention describes surfactants of formula (I), wherein R, RN, and m are defined herein, processes for their preparation, and methods for their decomposition.Type: GrantFiled: March 22, 2006Date of Patent: May 27, 2008Assignee: Sandia CorporationInventors: James R. McElhanon, Gregory M. Jamison, Timothy M. Long, Douglas A. Loy, Kamyar Rahimian, Blake A. Simmons, Chad L. Staiger, David R. Wheeler, Thomas Zifer
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Patent number: 7358221Abstract: A class of surfactant molecules whose structure includes regularly spaced unsaturation in the tail group and thus, can be readily decomposed by ring-closing metathesis, and particularly by the action of a transition metal catalyst, to form small molecule products. These small molecules are designed to have increased volatility and/or enhanced solubility as compared to the original surfactant molecule and are thus easily removed by solvent extraction or vacuum extraction at low temperature. By producing easily removable decomposition products, the surfactant molecules become particularly desirable as template structures for preparing meso- and microstructural materials with tailored properties.Type: GrantFiled: June 26, 2006Date of Patent: April 15, 2008Assignee: Sandia CorporationInventors: Gregory M. Jamison, David R. Wheeler, Douglas A. Loy, Blake A. Simmons, Timothy M. Long, James R. McElhanon, Kamyar Rahimian, Chad L. Staiger
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Patent number: 7351837Abstract: The present invention describes surfactants of formula (I), wherein R, RN, and m are defined herein, processes for their preparation, and methods for their decomposition.Type: GrantFiled: March 22, 2006Date of Patent: April 1, 2008Assignee: Sandia CorporationInventors: James R. McElhanon, Gregory M. Jamison, Timothy M. Long, Douglas A. Loy, Kamyar Rahimian, Blake A. Simmons, Chad L. Staiger, David R. Wheeler, Thomas Zifer