Low temperature catalytic reverse water gas shift reaction assisted by an electric field

Kazumasa Oshima; Tatsuya Shinagawa; Yukako Nogami; Ryo Manabe; Shuhei Ogo; Yasushi Sekine

doi:10.1016/j.cattod.2013.11.035

Low temperature catalytic reverse water gas shift reaction assisted by an electric field

Kazumasa Oshima, Tatsuya Shinagawa, Yukako Nogami, Ryo Manabe, Shuhei Ogo, Yasushi Sekine^*

^*Corresponding author for this work

School of Advanced Science and Engineering

Research output: Contribution to journal › Article › peer-review

103 Citations (Scopus)

Abstract

Catalytic reverse water gas shift reaction was conducted in an electric field (denoted as E-RWGS) over various catalysts at low temperature as 423 K. A platinum catalyst supported on lanthanum doped zirconia (Pt/La-ZrO₂) showed the highest yield (ca. 40%) for the E-RWGS reaction even at such low temperature condition. In contrast to a bare oxide catalyst, metal loading catalysts showed higher activities and efficiencies for the reaction. Roles of the impregnated platinum and doped lanthanum on the catalytic activity were investigated, and we found that loaded platinum worked as an active site for the E-RWGS reaction, and La doping stabilized the structure of ZrO₂. The effect of the electric field was discussed based on thermodynamic evaluation and experimental results.

Original language	English
Pages (from-to)	27-32
Number of pages	6
Journal	Catalysis Today
Volume	232
DOIs	https://doi.org/10.1016/j.cattod.2013.11.035
Publication status	Published - 2014 Sept 1

Keywords

Carbon dioxide
Catalytic reaction
Electric field
Reverse water gas shift

ASJC Scopus subject areas

Catalysis
Chemistry(all)

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10.1016/j.cattod.2013.11.035

Cite this

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title = "Low temperature catalytic reverse water gas shift reaction assisted by an electric field",

abstract = "Catalytic reverse water gas shift reaction was conducted in an electric field (denoted as E-RWGS) over various catalysts at low temperature as 423 K. A platinum catalyst supported on lanthanum doped zirconia (Pt/La-ZrO2) showed the highest yield (ca. 40%) for the E-RWGS reaction even at such low temperature condition. In contrast to a bare oxide catalyst, metal loading catalysts showed higher activities and efficiencies for the reaction. Roles of the impregnated platinum and doped lanthanum on the catalytic activity were investigated, and we found that loaded platinum worked as an active site for the E-RWGS reaction, and La doping stabilized the structure of ZrO2. The effect of the electric field was discussed based on thermodynamic evaluation and experimental results.",

keywords = "Carbon dioxide, Catalytic reaction, Electric field, Reverse water gas shift",

author = "Kazumasa Oshima and Tatsuya Shinagawa and Yukako Nogami and Ryo Manabe and Shuhei Ogo and Yasushi Sekine",

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TY - JOUR

T1 - Low temperature catalytic reverse water gas shift reaction assisted by an electric field

AU - Oshima, Kazumasa

AU - Shinagawa, Tatsuya

AU - Nogami, Yukako

AU - Manabe, Ryo

AU - Ogo, Shuhei

AU - Sekine, Yasushi

PY - 2014/9/1

Y1 - 2014/9/1

N2 - Catalytic reverse water gas shift reaction was conducted in an electric field (denoted as E-RWGS) over various catalysts at low temperature as 423 K. A platinum catalyst supported on lanthanum doped zirconia (Pt/La-ZrO2) showed the highest yield (ca. 40%) for the E-RWGS reaction even at such low temperature condition. In contrast to a bare oxide catalyst, metal loading catalysts showed higher activities and efficiencies for the reaction. Roles of the impregnated platinum and doped lanthanum on the catalytic activity were investigated, and we found that loaded platinum worked as an active site for the E-RWGS reaction, and La doping stabilized the structure of ZrO2. The effect of the electric field was discussed based on thermodynamic evaluation and experimental results.

AB - Catalytic reverse water gas shift reaction was conducted in an electric field (denoted as E-RWGS) over various catalysts at low temperature as 423 K. A platinum catalyst supported on lanthanum doped zirconia (Pt/La-ZrO2) showed the highest yield (ca. 40%) for the E-RWGS reaction even at such low temperature condition. In contrast to a bare oxide catalyst, metal loading catalysts showed higher activities and efficiencies for the reaction. Roles of the impregnated platinum and doped lanthanum on the catalytic activity were investigated, and we found that loaded platinum worked as an active site for the E-RWGS reaction, and La doping stabilized the structure of ZrO2. The effect of the electric field was discussed based on thermodynamic evaluation and experimental results.

KW - Carbon dioxide

KW - Catalytic reaction

KW - Electric field

KW - Reverse water gas shift

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JO - Catalysis Today

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Low temperature catalytic reverse water gas shift reaction assisted by an electric field

Abstract

Keywords

ASJC Scopus subject areas

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