Patents by Inventor Rebecca Potash
Rebecca Potash 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: 11118078Abstract: Low temperature processes for converting mixtures of metal inks into alloys. The alloys can be dealloyed by etching. A method comprising: depositing at least one precursor composition on at least one substrate to form at least one deposited structure, wherein the precursor composition comprises at least two metal complexes, including at least one first metal complex comprising at least one first metal and at least one second metal complex different from the first metal complex and comprising at least one second metal different from the first metal, treating the deposited structure so that the first metal and the second metal become elemental forms of the first metal and the second metal in a treated structure. Further, one can remove at least some of the first metal to leave a nanoporous material comprising at least the second metal. Precursor compositions can be formulated to be homogeneous compositions.Type: GrantFiled: August 3, 2020Date of Patent: September 14, 2021Assignee: Liquid X Printed Metals, Inc.Inventors: Richard D McCullough, John Belot, Rebecca Potash
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Publication number: 20200362188Abstract: Low temperature processes for converting mixtures of metal inks into alloys. The alloys can be dealloyed by etching. A method comprising: depositing at least one precursor composition on at least one substrate to form at least one deposited structure, wherein the precursor composition comprises at least two metal complexes, including at least one first metal complex comprising at least one first metal and at least one second metal complex different from the first metal complex and comprising at least one second metal different from the first metal, treating the deposited structure so that the first metal and the second metal become elemental forms of the first metal and the second metal in a treated structure. Further, one can remove at least some of the first metal to leave a nanoporous material comprising at least the second metal. Precursor compositions can be formulated to be homogeneous compositions.Type: ApplicationFiled: August 3, 2020Publication date: November 19, 2020Applicant: Liquid X Printed Metals, Inc.Inventors: Richard D McCullough, John Belot, Rebecca Potash
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Patent number: 10738211Abstract: Low temperature processes for converting mixtures of metal inks into alloys. The alloys can be dealloyed by etching. A method comprising: depositing at least one precursor composition on at least one substrate to form at least one deposited structure, wherein the precursor composition comprises at least two metal complexes, including at least one first metal complex comprising at least one first metal and at least one second metal complex different from the first metal complex and comprising at least one second metal different from the first metal, treating the deposited structure so that the first metal and the second metal become elemental forms of the first metal and the second metal in a treated structure. Further, one can remove at least some of the first metal to leave a nanoporous material comprising at least the second metal. Precursor compositions can be formulated to be homogeneous compositions.Type: GrantFiled: March 16, 2018Date of Patent: August 11, 2020Assignee: Liquid X Printed Metals, Inc.Inventors: Richard D. McCullough, John Belot, Rebecca Potash
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Patent number: 10079401Abstract: A redox flow battery comprising: a positive compartment containing a positive electrode in contact with a liquid electrolyte comprised of an organic redox active molecule dissolved in a solvent; a negative compartment containing a negative electrode in contact with a liquid electrolyte comprised of said organic redox active molecule dissolved in a solvent; electrical communication means for establishing electrical communication between said positive electrode, said negative electrode and an external load for directing electrical energy into or out of said symmetric redox flow battery; a separator component that separates the electrolyte solutions in the positive and negative compartments while permitting the passage of non-redox-active species between electrolyte solutions in positive and negative compartments; and means capable of establishing flow of the electrolyte solutions past said positive and negative electrodes, respectively.Type: GrantFiled: March 23, 2015Date of Patent: September 18, 2018Assignee: CORNELL UNIVERSITYInventors: Rebecca Potash, James R. McKone, Hector D. Abruna, Sean Conte
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Publication number: 20180208790Abstract: Low temperature processes for converting mixtures of metal inks into alloys. The alloys can be dealloyed by etching. A method comprising: depositing at least one precursor composition on at least one substrate to form at least one deposited structure, wherein the precursor composition comprises at least two metal complexes, including at least one first metal complex comprising at least one first metal and at least one second metal complex different from the first metal complex and comprising at least one second metal different from the first metal, treating the deposited structure so that the first metal and the second metal become elemental forms of the first metal and the second metal in a treated structure. Further, one can remove at least some of the first metal to leave a nanoporous material comprising at least the second metal. Precursor compositions can be formulated to be homogeneous compositions.Type: ApplicationFiled: March 16, 2018Publication date: July 26, 2018Applicant: LIQUID X PRINTED METALS, INC.Inventors: Richard D. McCullough, Rebecca Potash
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Patent number: 9920212Abstract: Low temperature processes for converting mixtures of metal inks into alloys. The alloys can be dealloyed by etching. A method comprising: depositing at least one precursor composition on at least one substrate to form at least one deposited structure, wherein the precursor composition comprises at least two metal complexes, including at least one first metal complex comprising at least one first metal and at least one second metal complex different from the first metal complex and comprising at least one second metal different from the first metal, treating the deposited structure so that the first metal and the second metal become elemental forms of the first metal and the second metal in a treated structure. Further, one can remove at least some of the first metal to leave a nanoporous material comprising at least the second metal. Precursor compositions can be formulated to be homogeneous compositions.Type: GrantFiled: May 20, 2016Date of Patent: March 20, 2018Assignee: Liquid X Printed Metals, Inc.Inventors: Richard D. McCullough, John Belot, Rebecca Potash
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Publication number: 20170187059Abstract: A redox flow battery comprising: a positive compartment containing a positive electrode in contact with a liquid electrolyte comprised of an organic redox active molecule dissolved in a solvent; a negative compartment containing a negative electrode in contact with a liquid electrolyte comprised of said organic redox active molecule dissolved in a solvent; electrical communication means for establishing electrical communication between said positive electrode, said negative electrode and an external load for directing electrical energy into or out of said symmetric redox flow battery; a separator component that separates the electrolyte solutions in the positive and negative compartments while permitting the passage of non-redox-active species between electrolyte solutions in positive and negative compartments; and means capable of establishing flow of the electrolyte solutions past said positive and negative electrodes, respectively.Type: ApplicationFiled: March 23, 2015Publication date: June 29, 2017Applicant: CORNELL UNIVERSITYInventors: Rebecca POTASH, James R. MCKONE, Hector D. ABRUNA, Sean CONTE
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Patent number: 9487669Abstract: Low temperature processes for converting mixtures of metal inks into alloys. The alloys can be dealloyed by etching. A method comprising: depositing at least one precursor composition on at least one substrate to form at least one deposited structure, wherein the precursor composition comprises at least two metal complexes, including at least one first metal complex comprising at least one first metal and at least one second metal complex different from the first metal complex and comprising at least one second metal different from the first metal, treating the deposited structure so that the first metal and the second metal form elemental forms of the first metal and the second metal in a treated structure. Further, one can remove at least some of the first metal to leave a nanoporous material comprising at least the second metal. Precursor compositions can be formulated to be homogeneous compositions.Type: GrantFiled: May 4, 2012Date of Patent: November 8, 2016Assignee: LIQUID X PRINTED METALS, INC.Inventors: Richard D. McCullough, John Belot, Rebecca Potash
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Publication number: 20160264802Abstract: Low temperature processes for converting mixtures of metal inks into alloys. The alloys can be dealloyed by etching. A method comprising: depositing at least one precursor composition on at least one substrate to form at least one deposited structure, wherein the precursor composition comprises at least two metal complexes, including at least one first metal complex comprising at least one first metal and at least one second metal complex different from the first metal complex and comprising at least one second metal different from the first metal, treating the deposited structure so that the first metal and the second metal become elemental forms of the first metal and the second metal in a treated structure. Further, one can remove at least some of the first metal to leave a nanoporous material comprising at least the second metal. Precursor compositions can be formulated to be homogeneous compositions.Type: ApplicationFiled: May 20, 2016Publication date: September 15, 2016Applicant: LIQUID X PRINTED METALS, INC.Inventors: Richard D. McCullough, John Belot, Rebecca Potash
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Publication number: 20130236656Abstract: Metal complexes adapted to form metallic conductive films upon deposition and treatment. The complexes can have a high concentration of metal and can be soluble in polar protic solvent including ethanol and water. The metal complex can be a covalent complex and can comprise a first and second ligand. Low temperature treatment can be used to convert the complex to a metal. The metallic conductive film can have low resistivity and work function close to pure metal. Coinage metals can be used (e.g., Ag). The ligands can be dative bonding ligands including amines and carboxylate ligands. The ligands can be adapted to volatilize well. High yields of metal can be achieve with high conductivity.Type: ApplicationFiled: February 26, 2013Publication date: September 12, 2013Applicant: Liquid X Printed Metals, Inc.Inventors: Richard D. MCCULLOUGH, John BELOT, Rebecca POTASH, Elizabeth SEFTON, Christiana COX
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Publication number: 20120304889Abstract: Low temperature processes for converting mixtures of metal inks into alloys. The alloys can be dealloyed by etching. A method comprising: depositing at least one precursor composition on at least one substrate to form at least one deposited structure, wherein the precursor composition comprises at least two metal complexes, including at least one first metal complex comprising at least one first metal and at least one second metal complex different from the first metal complex and comprising at least one second metal different from the first metal, treating the deposited structure so that the first metal and the second metal form elemental forms of the first metal and the second metal in a treated structure. Further, one can remove at least some of the first metal to leave a nanoporous material comprising at least the second metal. Precursor compositions can be formulated to be homogeneous compositions.Type: ApplicationFiled: May 4, 2012Publication date: December 6, 2012Inventors: Richard D. MCCULLOUGH, John BELOT, Rebecca POTASH
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Publication number: 20110111138Abstract: Metal complexes adapted to form conductive metal films and lines upon deposition and treatment. The metal complex can be a covalent complex and can comprise a first and second ligand. Low temperature treatment can be used to convert the complex to a metal. The metal films and lines can have low resistivity and work function similar to pure metal. Coinage metals can be used (e.g., Ag, Au, Cu). The ligands can be dative bonding ligands including amines, unsymmetrical amines, and carboxylate ligands. Sulfur complexes can be used. Carboxylate ligands can be used. The complexes can have a high concentration of metal and can be soluble in aromatic hydrocarbon solvent. The ligands can be adapted to volatilize well. Inkjet printing can be carried out. High yields of metal can be achieve with high conductivity.Type: ApplicationFiled: November 8, 2010Publication date: May 12, 2011Inventors: Richard D. McCullough, John A. Belot, Anna Javier, Rebecca Potash