Abstract: Nanoporous oxygen reduction catalyst material comprising PtNiIr. The nanoporous oxygen reduction catalyst material is useful, for example, in fuel cell membrane electrode assemblies.

Abstract: An iridium-based catalyst and method of making the catalyst are described. The catalyst comprises a catalytic material comprising iridium oxide or a mixture of iridium and iridium oxide nanoplates. It may have a BET surface area of at least 50 m2/g and a pore volume of at least 0.10 cc/g. The nanoplates are less than 50 nm thick. The catalyst is made using organic and inorganic structure directing agents.

Abstract: Catalyst-coated ionically conductive membranes are described. The catalyst-coated ionically conductive membranes comprise an ionically conductive membrane, an anode catalyst coating layer on a first surface of the ionically conductive membrane, or, a cathode catalyst coating layer on a second surface of the ionically conductive membrane, or both wherein the anode catalyst coating layer, or the cathode catalyst coating layer, or both comprises a conductive polymer. Membrane electrode assemblies and electrolysis systems incorporating the catalyst-coated ionically conductive membranes are also described.

Abstract: Water electrolysis catalysts having reduced precious metal loading which are highly active and stable and methods of preparing the water electrolysis catalysts are described. The methods involve depositing a substantially continuous thin shell layer of a platinum group metal (PGM)-based precursor on a nano-sized inorganic oxide core to form a coated inorganic oxide core. The coated inorganic oxide core is heated in the presence of a template to convert the substantially continuous thin shell layer of the PGM-based precursor to a substantially continuous thin shell layer of PGM oxide. The template is then removed forming a water electrolysis catalyst comprising the nano-sized inorganic oxide core having a substantially continuous thin shell layer of the PGM oxide. The water electrolysis catalyst comprises less than 30 wt% of the PGM oxide.

Abstract: A start-up process for conditioning an electrolysis system containing ionically conductive membrane, such as a polyelectrolyte multilayer coated proton exchange membranes, to reduce the break-in period is described. The conditioning involves heating the electrolysis feed, the electrolysis system, or both at a temperature above the desired operating temperature to achieve faster startup. In some cases, the voltage is controlled to avoid damage to the sample.

Abstract: Processes for treating a fiber substrate are disclosed. A fiber substrate comprising borosilicate with acidic functional groups. A metal salt solution is introduced to the fiber substrate. The metal salt solution includes cations having an ionic charge of +2 or greater. The pH of the metal salt solution may be adjusted, and the cations are deposited on the glass fibers. The treated fiber substrate may be utilized to form a filter media.

Abstract: Nanoporous oxygen reduction catalyst material comprising PtNiIr. The nanoporous oxygen reduction catalyst material is useful, for example, in fuel cell membrane electrode assemblies.

Abstract: Processes for increasing the viricidal activity of a fiber substrate. The fiber substrate is provided. An antiviral treatment containing a quaternary ammonium or phosphonium compound is introduced to the fiber substrate to form an antiviral substrate. The treated fiber substrate is washed and dried. The antiviral treatment may occur before or after the fiber substrate is incorporated into the HEPA filter media in a papermaking process. Also a filter made from treated fiber substrates.

Abstract: Processes for increasing a virucidal activity of a fiber substrate are disclosed. A fiber substrate comprising borosilicate is provided. The fiber substrate may comprise acidic functional groups. An antiviral metal salt solution is introduced to the fiber substrate to form an antiviral substrate. The pH of the antiviral metal salt solution is adjusted, and an antiviral metal ion is exchanged with a proton from the acidic functional groups. The antiviral metal is present in an amount ranging from about 0.001 to about 3.0 wt. % of the antiviral fiber substrate. The antiviral fiber substrate is incorporated into a filter media before or after the deposition of the antiviral metal onto the fiber substrate.

Abstract: Processes for increasing a viricidal activity of a fiber substrate. The fiber substrate is provided. The fiber substrate may comprise acidic functional groups and may be acid leached to provide additional acidic groups. Metal ions may thereafter be exchanged with a proton from the acidic functional groups. A divalent metal is introduced to the fiber substrate. An antiviral metal is introduced and deposited onto the fiber substrate by galvanic displacement. Subsequently, a further antiviral metal is introduced and deposited on the fiber substrate by an electroless process. The treated fiber substrate is washed and dried. The deposition of antiviral metals onto the fiber substrate to form a treated fiber substrate may occur before or after the fiber substrate is incorporated into a filter media in a wet-laid paper making process.

Abstract: Nanoporous oxygen reduction catalyst material comprising PtNiIr, the catalyst material preferably having the formula PtxNiyIrz, wherein x is in a range from 26.6 to 47.8, y is in a range from 48.7 to 70, and z is in a range from 1 to 11.4. The nanoporous oxygen reduction catalyst material is useful, for example, in fuel cell membrane electrode assemblies.

Abstract: Nanoporous oxygen reduction catalyst material comprising PtNiAu. The nanoporous oxygen reduction catalyst material is useful, for example, in fuel cell membrane electrode assemblies.

Abstract: Catalysts comprising nanostructured elements comprising microstructured whiskers having an outer surface at least partially covered by a catalyst material having the formula PtxNiyAuz, wherein x is in a range from 27.3 to 29.9, y is in a range from 63.0 to 70.0, and z is in a range from 0.1 to 9.6. Catalyst described herein are useful, for example, in fuel cell membrane electrode assemblies.

Abstract: Membrane electrode assembly comprising oxygen evolution reaction catalyst disposed in gas distribution layer (100, 700) or between gas distribution layer (100, 700 and gas dispersion layer (200, 600). Membrane electrode assemblies described herein are useful, for example, in electrochemical devices such as a fuel cell.

Abstract: Nanoporous oxygen reduction catalyst material comprising PtNiIr, the catalyst material preferably having the formula PtxNiyIrz, wherein x is in a range from 26.6 to 47.8, y is in a range from 48.7 to 70, and z is in a range from 1 to 11.4. The nanoporous oxygen reduction catalyst material is useful, for example, in fuel cell membrane electrode assemblies.

Abstract: Catalyst (100) comprising nanostructured elements (102) comprising microstructured whiskers (104) having an outer surface (105) at least partially covered by a catalyst material (106) having the formula PtxNiyIrz, wherein x is in a range from 26.6 to 47.8, y is in a range from 48.7 to 70, and z is in a range from 1 to 11.4. Catalysts described herein are useful, for example, in fuel cell membrane electrode assemblies.

Abstract: Catalysts comprising nanostructured elements comprising microstructured whiskers having an outer surface at least partially covered by a catalyst material having the formula PtxNiyAuz, wherein x is in a range from 27.3 to 29.9, y is in a range from 63.0 to 70.0, and z is in a range from 0.1 to 9.6. Catalyst described herein are useful, for example, in fuel cell membrane electrode assemblies.

Abstract: Nanoporous oxygen reduction catalyst material comprising PtNiAu. The nanoporous oxygen reduction catalyst material is useful, for example, in fuel cell membrane electrode assemblies.

Abstract: Membrane electrode assembly comprising oxygen evolution reaction catalyst disposed in gas distribution layer (100, 700) or between gas distribution layer (100, 700 and gas dispersion layer (200, 600). Membrane electrode assemblies described herein are useful, for example, in electrochemical devices such as a fuel cell.

Abstract: Fuel cell anodes comprising (a) a catalyst comprising Pt, (b) an oxygen evolution reaction catalyst, and (c) at least one of Au, a refractory metal (e.g., at least one of Hf, Nb, Os, Re, Rh, Ta, Ti, W, or Zr), a refractory metal oxide, a refractory metal boride, a refractory metal carbide, a refractory metal nitride, or a refractory metal silicide. The fuel cell anodes are useful in fuel cells.