Patents by Inventor Deborah J. Myers
Deborah J. Myers 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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Publication number: 20240384425Abstract: A method of improving Faradaic efficiency in an electrochemical device includes providing a catalyst at an electrode of the electrochemical device. The catalyst includes a nanoparticle comprising a metal or metal alloy. The nanoparticle is selected to improve catalytic performance in the electrochemical device. The catalyst further includes an electron-conductive nano-zeolitic framework encasing the nanoparticle. The nano-zeolitic framework includes a hollow three-dimensional framework defining a catalyst surface, an internal cavity in which the nanoparticle is disposed, and a plurality of pores extending through the nano-zeolitic framework. The plurality of pores have a size and shape selected to block molecules corresponding to undesired reactions in the electrochemical device. The method further includes selectively promoting a desired reaction at the catalyst surface and selectively blocking the undesired reactions at the catalyst surface.Type: ApplicationFiled: May 2, 2024Publication date: November 21, 2024Applicant: UCHICAGO ARGONNE LLCInventors: Ahmed A. Farghaly, Deborah J. Myers
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Patent number: 12027711Abstract: An efficient, stable catalyst material having a thin film catalyst supported on a support of metal carbide, nitride, oxide, carbonitride, oxycarbonitride core. The thin film catalyst comprises a catalytic metal selected from the group consisting of platinum-group metals, platinum-group metal oxides, transition metals, transition metal oxides, and combinations thereof. The thin film catalyst is covalently bonded to the support.Type: GrantFiled: October 9, 2018Date of Patent: July 2, 2024Assignee: UChicago Argonne, LLCInventors: Alizera Pezhman Shirvanian, Deborah J. Myers, Jeffrey W. Elam
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Patent number: 11581547Abstract: Systems for creating electrodes for polymer electrolyte membrane fuel cells include an XY stage having a heated vacuum table physically coupled to the XY stage. The vacuum table has a working face with a plurality of channels formed therein to communicate vacuum pressure from a port coupled to a vacuum source to the channels. A sheet of perforated heat-conductive material has staggered holes configured to evenly distribute the vacuum pressure from the channels through the perforated sheet. A heat-conductive wire mesh is placed over the perforated sheet, and has openings smaller than the staggered holes such that a membrane material placed on the wire mesh is not deformed by the vacuum pressure. A nanopipette or micropipette coupled to a pump is configured to deposit electrode ink onto an exposed surface of the membrane material as the controller device causes the XY stage to move the vacuum table to control deposition of the electrode ink onto the surface of the membrane material.Type: GrantFiled: May 29, 2019Date of Patent: February 14, 2023Assignee: UCHICAGO ARGONNE, LLCInventors: Jae Hyung Park, Deborah J. Myers
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Publication number: 20200381744Abstract: Systems for creating electrodes for polymer electrolyte membrane fuel cells include an XY stage having a heated vacuum table physically coupled to the XY stage. The vacuum table has a working face with a plurality of channels formed therein to communicate vacuum pressure from a port coupled to a vacuum source to the channels. A sheet of perforated heat-conductive material has staggered holes configured to evenly distribute the vacuum pressure from the channels through the perforated sheet. A heat-conductive wire mesh is placed over the perforated sheet, and has openings smaller than the staggered holes such that a membrane material placed on the wire mesh is not deformed by the vacuum pressure. A nanopipette or micropipette coupled to a pump is configured to deposit electrode ink onto an exposed surface of the membrane material as the controller device causes the XY stage to move the vacuum table to control deposition of the electrode ink onto the surface of the membrane material.Type: ApplicationFiled: May 29, 2019Publication date: December 3, 2020Inventors: Jae Hyung Park, Deborah J. Myers
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Publication number: 20190109330Abstract: An efficient, stable catalyst material having a thin film catalyst supported on a support of metal carbide, nitride, oxide, carbonitride, oxycarbonitride core. The thin film catalyst is covalently bonded to the support.Type: ApplicationFiled: October 9, 2018Publication date: April 11, 2019Applicant: UChicago Argonne, LLCInventors: Alizera Pezhman Shirvanian, Deborah J. Myers, Jeffrey W. Elam
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Patent number: 9929453Abstract: A lithium-air battery cathode catalyst includes core-shell nanoparticles on a carbon support, wherein: a core of the core-shell nanoparticles is platinum metal; and a shell of the core-shell nanoparticles is copper metal; wherein: the core-shell nanoparticles have a weight ratio of the copper metal to the platinum metal from about 4% to about 6% copper to from about 2% to about 12% platinum, with a remaining percentage being the carbon support.Type: GrantFiled: August 4, 2014Date of Patent: March 27, 2018Assignee: UCHICAGO ARGONNE, LLCInventors: Jun Lu, Khalil Amine, Xiaoping Wang, Xiangyi Luo, Deborah J. Myers
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Patent number: 9421521Abstract: A surface segregated bimetallic composition of the formula Ru1-xIrx wherein 0.1?x?0.75, wherein a surface of the material has an Ir concentration that is greater than an Ir concentration of the material as a whole is provided. The surface segregated material may be produced by a method including heating a bimetallic composition of the formula Ru1-xIrx, wherein 0.1?x?0.75, at a first temperature in a reducing environment, and heating the composition at a second temperature in an oxidizing environment. The surface segregated material may be utilized in electrochemical devices.Type: GrantFiled: September 30, 2014Date of Patent: August 23, 2016Assignee: UCHICAGO ARGONNE, LLCInventors: Nemanja Danilovic, Yijin Kang, Nenad Markovic, Vojislav Stamenkovic, Deborah J. Myers, Ram Subbaraman
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Publication number: 20160089658Abstract: A surface segregated bimetallic composition of the formula Ru1-xIrx wherein 0.1?x?0.75, wherein a surface of the material has an Ir concentration that is greater than an Ir concentration of the material as a whole is provided. The surface segregated material may be produced by a method including heating a bimetallic composition of the formula Ru1-xIrx, wherein 0.1?x?0.75, at a first temperature in a reducing environment, and heating the composition at a second temperature in an oxidizing environment. The surface segregated material may be utilized in electrochemical devices.Type: ApplicationFiled: September 30, 2014Publication date: March 31, 2016Inventors: Nemanja Danilovic, Yijin Kang, Nenad Markovic, Vojislav Stamenkovic, Deborah J. Myers, Ram Subbaraman
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Publication number: 20160036108Abstract: A lithium-air battery cathode catalyst includes core-shell nanoparticles on a carbon support, wherein: a core of the core-shell nanoparticles is platinum metal; and a shell of the core-shell nanoparticles is copper metal; wherein: the core-shell nanoparticles have a weight ratio of the copper metal to the platinum metal from about 4% to about 6% copper to from about 2% to about 12% platinum, with a remaining percentage being the carbon support.Type: ApplicationFiled: August 4, 2014Publication date: February 4, 2016Inventors: Jun Lu, Khalil Amine, Xiaoping Wang, Xiangyi Luo, Deborah J. Myers
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Patent number: 8652709Abstract: Methods of sealing a bipolar plate supported solid oxide fuel cell with a sealed anode compartment are provided. The solid oxide fuel cell includes a cathode, an electrolyte, and an anode, which are supported on a metallic bipolar plate assembly including gas flow fields and the gas impermeable bipolar plate. The electrolyte and anode are sealed into an anode compartment with a metal perimeter seal. An improved method of sealing is provided by extending the metal seal around the entire perimeter of the cell between an electrolyte and the bipolar plate to form the anode compartment. During a single-step high temperature sintering process the metal seal bonds to the edges of the electrolyte and anode layers, the metal foam flow field and the bipolar plate to form a gastight containment.Type: GrantFiled: November 11, 2009Date of Patent: February 18, 2014Assignee: UChicago Argonne, LLCInventors: John David Carter, Joong-Myeon Bae, Terry Alan Cruse, James Michael Ralph, Deborah J. Myers
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Patent number: 8129306Abstract: A polymetallic nanoparticle alloy having enhanced catalytic properties including at least one noble metal and at least one base metal, where the noble metal is preferentially dispersed near the surface of the nanoparticle and the base metal modifies the electronic properties of the surface disposed noble metal. The polymetallic nanoparticles having application as a catalyst when dispersed on a carbon substrate and in particular applications in a fuel cell. In various embodiments a bimetallic noble metal-base metal nanoparticle alloy may be used as an electrocatalyst offering enhanced ORR activity compared to the monometallic electrocatalyst of noble metal.Type: GrantFiled: January 28, 2009Date of Patent: March 6, 2012Assignee: UChicago Argonne, LLCInventors: Deborah J. Myers, Xiaoping Wang, Nancy N. Kariuki
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Publication number: 20100064508Abstract: Methods of sealing a bipolar plate supported solid oxide fuel cell with a sealed anode compartment are provided. The solid oxide fuel cell includes a cathode, an electrolyte, and an anode, which are supported on a metallic bipolar plate assembly including gas flow fields and the gas impermeable bipolar plate. The electrolyte and anode are sealed into an anode compartment with a metal perimeter seal. An improved method of sealing is provided by extending the metal seal around the entire perimeter of the cell between an electrolyte and the bipolar plate to form the anode compartment. During a single-step high temperature sintering process the metal seal bonds to the edges of the electrolyte and anode layers, the metal foam flow field and the bipolar plate to form a gastight containment.Type: ApplicationFiled: November 11, 2009Publication date: March 18, 2010Applicant: UCHICAGO ARGONNE, LLCInventors: John David Carter, Joong-Myeon Bae, Terry Alan Cruse, James Michael Ralph, Deborah J. Myers
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Patent number: 7632593Abstract: A bipolar plate supported solid oxide fuel cell with a sealed anode compartment is provided. The solid oxide fuel cell includes a cathode, an electrolyte, and an anode, which are supported on a metallic bipolar plate assembly including gas flow fields and the gas impermeable bipolar plate. The electrolyte and anode are sealed into an anode compartment with a metal perimeter seal. An improved method of sealing is provided by extending the metal seal around the entire perimeter of the cell between an electrolyte and the bipolar plate to form the anode compartment. During a single-step high temperature sintering process the metal seal bonds to the edges of the electrolyte and anode layers, the metal foam flow field and the bipolar plate to form a gastight containment.Type: GrantFiled: April 18, 2006Date of Patent: December 15, 2009Assignee: UChicago Argonne, LLCInventors: John David Carter, Joong-Myeon Bae, Terry Alan Cruse, James Michael Ralph, Deborah J. Myers
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Publication number: 20090192030Abstract: A polymetallic nanoparticle alloy having enhanced catalytic properties including at least one noble metal and at least one base metal, where the noble metal is preferentially dispersed near the surface of the nanoparticle and the base metal modifies the electronic properties of the surface disposed noble metal. The polymetallic nanoparticles having application as a catalyst when dispersed on a carbon substrate and in particular applications in a fuel cell. In various embodiments a bimetallic noble metal-base metal nanoparticle alloy may be used as an electrocatalyst offering enhanced ORR activity compared to the monometallic electrocatalyst of noble metal.Type: ApplicationFiled: January 28, 2009Publication date: July 30, 2009Inventors: Deborah J. Myers, Xiaoping Wang, Nancy N. Kariuki
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Patent number: 7563292Abstract: A method of producing a H2 rich gas stream includes supplying an O2 rich gas, steam, and fuel to an inner reforming zone of a fuel processor that includes a partial oxidation catalyst and a steam reforming catalyst or a combined partial oxidation and stream reforming catalyst. The method also includes contacting the O2 rich gas, steam, and fuel with the partial oxidation catalyst and the steam reforming catalyst or the combined partial oxidation and stream reforming catalyst in the inner reforming zone to generate a hot reformate stream. The method still further includes cooling the hot reformate stream in a cooling zone to produce a cooled reformate stream. Additionally, the method includes removing sulfur-containing compounds from the cooled reformate stream by contacting the cooled reformate stream with a sulfur removal agent.Type: GrantFiled: February 27, 2004Date of Patent: July 21, 2009Assignee: UChicago Argonne, LLCInventors: Shabbir Ahmed, Sheldon H. D. Lee, John David Carter, Michael Krumpelt, Deborah J. Myers
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Patent number: 7195835Abstract: An ion conducting membrane comprising dendrimeric polymers covalently linked into a network structure. The dendrimeric polymers have acid functional terminal groups and may be covalently linked via linking compounds, cross-coupling reactions, or copolymerization reactions. The ion conducting membranes may be produced by various methods and used in fuel cells.Type: GrantFiled: December 1, 2005Date of Patent: March 27, 2007Assignee: UChicago Argonne, LLCInventors: Daniel G. Colombo, Michael Krumpelt, Deborah J. Myers, John P. Kopasz
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Patent number: 6977122Abstract: An ion conducting membrane comprising dendrimeric polymers covalently linked into a network structure. The dendrimeric polymers have acid functional terminal groups and may be covalently linked via linking compounds, cross-coupling reactions, or copolymerization reactions. The ion conducting membranes may be produced by various methods and used in fuel cells.Type: GrantFiled: March 25, 2002Date of Patent: December 20, 2005Assignee: The University of ChicagoInventors: Daniel G. Colombo, Michael Krumpelt, Deborah J. Myers, John P. Kopasz
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Publication number: 20040163311Abstract: A method of producing a H2 rich gas stream includes supplying an O2 rich gas, steam, and fuel to an inner reforming zone of a fuel processor that includes a partial oxidation catalyst and a steam reforming catalyst or a combined partial oxidation and stream reforming catalyst. The method also includes contacting the O2 rich gas, steam, and fuel with the partial oxidation catalyst and the steam reforming catalyst or the combined partial oxidation and stream reforming catalyst in the inner reforming zone to generate a hot reformate stream. The method still further includes cooling the hot reformate stream in a cooling zone to produce a cooled reformate stream. Additionally, the method includes removing sulfur-containing compounds from the cooled reformate stream by contacting the cooled reformate stream with a sulfur removal agent.Type: ApplicationFiled: February 27, 2004Publication date: August 26, 2004Inventors: Shabbir Ahmed, Sheldon H. D. Lee, John David Carter, Michael Krumpelt, Deborah J. Myers
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Publication number: 20030035991Abstract: The invention provides an ion conducting membrane comprising dendrimeric polymers covalently linked into a network structure. The dendrimeric polymers of the invention have acid functional terminal groups and may be covalently linked via linking compounds, cross-coupling reactions, or copolymerization reactions. The invention also provides methods for producing the ion conducting membranes and fuel cells made from the membranes.Type: ApplicationFiled: March 25, 2002Publication date: February 20, 2003Applicant: The University of ChicagoInventors: Daniel G. Colombo, Michael Krumpelt, Deborah J. Myers, John P. Kopasz