Your search keyword '"palladium-zirconium intermetallic phase"' showing total 5 results

1. Carbide-Modified Pd on ZrO(2)as Active Phase for CO2-Reforming of Methane-A Model Phase Boundary Approach

Author

Koepfle, Norbert, Ploner, Kevin, Lackner, Peter, Goetsch, Thomas, Thurner, Christoph, Carbonio, Emilia, Haevecker, Michael, Knop-Gericke, Axel, Schlicker, Lukas, Doran, Andrew, Kober, Delf, Gurlo, Aleksander, Willinger, Marc, Penner, Simon, Schmid, Michael, and Kloetzer, Bernhard

Subjects

palladium carbide, graphite, metal-support interaction, coking, palladium-zirconium intermetallic phase, in-situ X-ray photoelectron spectroscopy, in-situ X-ray diffraction, high resolution electron microscopy, dry reforming of methane, carbon dioxide activation, Physical Chemistry, Physical Chemistry (incl. Structural)

Abstract

Starting from subsurface Zr0-doped “inverse” Pd and bulk-intermetallic Pd0Zr0 model catalyst precursors, we investigated the dry reforming reaction of methane (DRM) using synchrotron-based near ambient pressure in-situ X-ray photoelectron spectroscopy (NAP-XPS), in-situ X-ray diffraction and catalytic testing in an ultrahigh-vacuum-compatible recirculating batch reactor cell. Both intermetallic precursors develop a Pd0–ZrO2 phase boundary under realistic DRM conditions, whereby the oxidative segregation of ZrO2 from bulk intermetallic PdxZry leads to a highly active composite layer of carbide-modified Pd0 metal nanoparticles in contact with tetragonal ZrO2. This active state exhibits reaction rates exceeding those of a conventional supported Pd–ZrO2 reference catalyst and its high activity is unambiguously linked to the fast conversion of the highly reactive carbidic/dissolved C-species inside Pd0 toward CO at the Pd/ZrO2 phase boundary, which serves the role of providing efficient CO2 activation sites. In contrast, the near-surface intermetallic precursor decomposes toward ZrO2 islands at the surface of a quasi-infinite Pd0 metal bulk. Strongly delayed Pd carbide accumulation and thus carbon resegregation under reaction conditions leads to a much less active interfacial ZrO2–Pd0 state.

Published

2020

2. Carbide-Modified Pd on ZrO2 as Active Phase for CO2-Reforming of Methane—A Model Phase Boundary Approach

Author

Köpfle, Norbert, Ploner, Kevin, Lackner, Peter, Götsch, Thomas, Thurner, Christoph, Carbonio, Emilia, Hävecker, Michael, Knop-Gericke, Axel, Schlicker, Lukas, Doran, Andrew, Kober, Delf, Gurlo, Aleksander, Willinger, Marc, Penner, Simon, Schmid, Michael, and Klötzer, Bernhard

Subjects

Engineering, Materials Engineering, Chemical Sciences, palladium carbide, graphite, metal-support interaction, coking, palladium-zirconium intermetallic phase, in-situ X-ray photoelectron spectroscopy, in-situ X-ray diffraction, high resolution electron microscopy, dry reforming of methane, carbon dioxide activation, Physical Chemistry (incl. Structural), Physical chemistry, Chemical engineering, Nanotechnology

Abstract

Starting from subsurface Zr0-doped “inverse” Pd and bulk-intermetallic Pd0Zr0 model catalyst precursors, we investigated the dry reforming reaction of methane (DRM) using synchrotron-based near ambient pressure in-situ X-ray photoelectron spectroscopy (NAP-XPS), in-situ X-ray diffraction and catalytic testing in an ultrahigh-vacuum-compatible recirculating batch reactor cell. Both intermetallic precursors develop a Pd0–ZrO2 phase boundary under realistic DRM conditions, whereby the oxidative segregation of ZrO2 from bulk intermetallic PdxZry leads to a highly active composite layer of carbide-modified Pd0 metal nanoparticles in contact with tetragonal ZrO2. This active state exhibits reaction rates exceeding those of a conventional supported Pd–ZrO2 reference catalyst and its high activity is unambiguously linked to the fast conversion of the highly reactive carbidic/dissolved C-species inside Pd0 toward CO at the Pd/ZrO2 phase boundary, which serves the role of providing efficient CO2 activation sites. In contrast, the near-surface intermetallic precursor decomposes toward ZrO2 islands at the surface of a quasi-infinite Pd0 metal bulk. Strongly delayed Pd carbide accumulation and thus carbon resegregation under reaction conditions leads to a much less active interfacial ZrO2–Pd0 state.

Published

2020

3. Carbide-Modified Pd on ZrO2 as Active Phase for CO2-Reforming of Methane—A Model Phase Boundary Approach

Author

Koepfle, Norbert, Ploner, Kevin, Lackner, Peter, Goetsch, Thomas, Thurner, Christoph, Carbonio, Emilia, Haevecker, Michael, Knop-Gericke, Axel, Schlicker, Lukas, Doran, Andrew, Kober, Delf, Gurlo, Aleksander, Willinger, Marc, Penner, Simon, Schmid, Michael, and Kloetzer, Bernhard

Subjects

palladium carbide, graphite, metal-support interaction, coking, palladium-zirconium intermetallic phase, in-situ X-ray photoelectron spectroscopy, in-situ X-ray diffraction, high resolution electron microscopy, dry reforming of methane, carbon dioxide activation, Physical Chemistry, ddc:540, Physical Chemistry (incl. Structural)

Abstract

Starting from subsurface Zr0-doped “inverse” Pd and bulk-intermetallic Pd0Zr0 model catalyst precursors, we investigated the dry reforming reaction of methane (DRM) using synchrotron-based near ambient pressure in-situ X-ray photoelectron spectroscopy (NAP-XPS), in-situ X-ray diffraction and catalytic testing in an ultrahigh-vacuum-compatible recirculating batch reactor cell. Both intermetallic precursors develop a Pd0–ZrO2 phase boundary under realistic DRM conditions, whereby the oxidative segregation of ZrO2 from bulk intermetallic PdxZry leads to a highly active composite layer of carbide-modified Pd0 metal nanoparticles in contact with tetragonal ZrO2. This active state exhibits reaction rates exceeding those of a conventional supported Pd–ZrO2 reference catalyst and its high activity is unambiguously linked to the fast conversion of the highly reactive carbidic/dissolved C-species inside Pd0 toward CO at the Pd/ZrO2 phase boundary, which serves the role of providing efficient CO2 activation sites. In contrast, the near-surface intermetallic precursor decomposes toward ZrO2 islands at the surface of a quasi-infinite Pd0 metal bulk. Strongly delayed Pd carbide accumulation and thus carbon resegregation under reaction conditions leads to a much less active interfacial ZrO2–Pd0 state. ISSN:2073-4344

Published

2020

4. Carbide-Modified Pd on ZrO2 as Active Phase for CO2-Reforming of Methane—A Model Phase Boundary Approach

Author

Andrew Doran, Thomas Götsch, Emilia A. Carbonio, Delf Kober, Aleksander Gurlo, Michael Schmid, Lukas Schlicker, Marc Willinger, Michael Hävecker, Christoph Thurner, Bernhard Klötzer, Axel Knop-Gericke, Norbert Köpfle, Kevin Ploner, Peter Lackner, and Simon Penner

Subjects

palladium carbide, graphite, metal-support interaction, coking, palladium-zirconium intermetallic phase, in-situ X-ray photoelectron spectroscopy, in-situ X-ray diffraction, high resolution electron microscopy, dry reforming of methane, carbon dioxide activation, Phase boundary, Materials science, Intermetallic, 02 engineering and technology, lcsh:Chemical technology, 010402 general chemistry, 01 natural sciences, 7. Clean energy, Catalysis, Methane, Carbide, metal support interaction, palladium zirconium intermetallic phase, in situ X ray photoelectron spectroscopy, in situ X ray diffraction, lcsh:Chemistry, Reaction rate, chemistry.chemical_compound, X-ray photoelectron spectroscopy, lcsh:TP1-1185, Physical and Theoretical Chemistry, Carbon dioxide reforming, 021001 nanoscience & nanotechnology, 0104 chemical sciences, 3. Good health, lcsh:QD1-999, Chemical engineering, chemistry, 0210 nano-technology

Abstract

Starting from subsurface Zr0-doped “inverse” Pd and bulk-intermetallic Pd0Zr0 model catalyst precursors, we investigated the dry reforming reaction of methane (DRM) using synchrotron-based near ambient pressure in-situ X-ray photoelectron spectroscopy (NAP-XPS), in-situ X-ray diffraction and catalytic testing in an ultrahigh-vacuum-compatible recirculating batch reactor cell. Both intermetallic precursors develop a Pd0–ZrO2 phase boundary under realistic DRM conditions, whereby the oxidative segregation of ZrO2 from bulk intermetallic PdxZry leads to a highly active composite layer of carbide-modified Pd0 metal nanoparticles in contact with tetragonal ZrO2. This active state exhibits reaction rates exceeding those of a conventional supported Pd–ZrO2 reference catalyst and its high activity is unambiguously linked to the fast conversion of the highly reactive carbidic/dissolved C-species inside Pd0 toward CO at the Pd/ZrO2 phase boundary, which serves the role of providing efficient CO2 activation sites. In contrast, the near-surface intermetallic precursor decomposes toward ZrO2 islands at the surface of a quasi-infinite Pd0 metal bulk. Strongly delayed Pd carbide accumulation and thus carbon resegregation under reaction conditions leads to a much less active interfacial ZrO2–Pd0 state.

Published

2020

5. Carbide-Modified Pd on ZrO2 as Active Phase for CO2-Reforming of Methane—A Model Phase Boundary Approach

Author

Köpfle, Norbert, Ploner, Kevin, Lackner, Peter, Götsch, Thomas, Thurner, Christoph, Carbonio, Emilia, Hävecker, Michael, Knop-Gericke, Axel, Schlicker, Lukas, Doran, Andrew, Kober, Delf, Gurlo, Aleksander, Willinger, Marc, Penner, Simon, Schmid, Michael, and Klötzer, Bernhard

Subjects

dry reforming of methane, carbon dioxide activation, graphite, palladium-zirconium intermetallic phase, coking, palladium carbide, in-situ X-ray diffraction, in-situ X-ray photoelectron spectroscopy, 7. Clean energy, high resolution electron microscopy, 3. Good health, metal-support interaction

Abstract

Starting from subsurface Zr0-doped “inverse” Pd and bulk-intermetallic Pd0Zr0 model catalyst precursors, we investigated the dry reforming reaction of methane (DRM) using synchrotron-based near ambient pressure in-situ X-ray photoelectron spectroscopy (NAP-XPS), in-situ X-ray diffraction and catalytic testing in an ultrahigh-vacuum-compatible recirculating batch reactor cell. Both intermetallic precursors develop a Pd0–ZrO2 phase boundary under realistic DRM conditions, whereby the oxidative segregation of ZrO2 from bulk intermetallic PdxZry leads to a highly active composite layer of carbide-modified Pd0 metal nanoparticles in contact with tetragonal ZrO2. This active state exhibits reaction rates exceeding those of a conventional supported Pd–ZrO2 reference catalyst and its high activity is unambiguously linked to the fast conversion of the highly reactive carbidic/dissolved C-species inside Pd0 toward CO at the Pd/ZrO2 phase boundary, which serves the role of providing efficient CO2 activation sites. In contrast, the near-surface intermetallic precursor decomposes toward ZrO2 islands at the surface of a quasi-infinite Pd0 metal bulk. Strongly delayed Pd carbide accumulation and thus carbon resegregation under reaction conditions leads to a much less active interfacial ZrO2–Pd0 state., Catalysts, 10 (9), ISSN:2073-4344