Support effects on catalysis of low temperature methane steam reforming

Support effects on catalysis of low temperature methane steam reforming

Low temperature ( Nb 2 O 5 > Ta 2 O 5. Surface proton conductivity has a key role for the activation of methane in an electric field. Proton hopping ability on the oxide surface was estimated using electrochemical impedance measurements. Proton transport ability on the oxide surface at 473 K was...

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Veröffentlicht in:RSC advances 2020-07, Vol.1 (44), p.26418-26424
Hauptverfasser: Torimoto, Maki, Ogo, Shuhei, Hisai, Yudai, Nakano, Naoya, Takahashi, Ayako, Ma, Quanbao, Seo, Jeong Gil, Tsuneki, Hideaki, Norby, Truls, Sekine, Yasushi
Format: Artikel
Sprache:eng
Schlagworte:
Catalysis
Catalysts
Catalytic activity
Cerium oxides
Chemistry
Electric fields
Low temperature
Methane
Niobium oxides
Pretreatment
Protons
Reforming
Steam electric power generation
Tantalum
Tantalum oxides
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Zusammenfassung:Low temperature ( Nb 2 O 5 > Ta 2 O 5. Surface proton conductivity has a key role for the activation of methane in an electric field. Proton hopping ability on the oxide surface was estimated using electrochemical impedance measurements. Proton transport ability on the oxide surface at 473 K was in the order of CeO 2 > Nb 2 O 5 > Ta 2 O 5. The OH group amounts on the oxide surface were evaluated by measuring pyridine adsorption with and without H 2 O pretreatment. Results indicate that the surface OH group concentrations on the oxide surface were in the order of CeO 2 > Nb 2 O 5 > Ta 2 O 5. These results demonstrate that the surface concentrations of OH groups are related to the proton hopping ability on the oxide surface. The concentrations reflect the catalytic activity of low-temperature methane steam reforming in the electric field. Low temperature (
ISSN:2046-2069
2046-2069
DOI:10.1039/d0ra04717a