The Mechanism of Direct Formic Acid Fuel Cell Using Pd, Pt and Pt-Ru
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概要
- 論文の詳細を見る
The electro-oxidation of formic acid, 2-propanol and methanol on Pd black, Pd/C, Pt-Ru/C and Pt/C has been investigated to clear the reaction mechanism. It was suggested that the formic acid is dehydrogenated on Pd surface and the hydrogen is occluded in the Pd lattice. Thus obtained hydrogen acts like pure hydrogen supplied from the outside and the cell performance of the direct formic acid fuel cell showed as high as that of a hydrogen-oxygen fuel cell. 2-propanol did not show such dehydrogenation reaction on Pd catalyst. Platinum and Pt-Ru accelerated the oxidation of C-OH of 2-propanol and methanol.Slow scan voltammogram (SSV) and chronoamperometry measurements showed that the activity of formic acid oxidation increased in the following order: Pd black > Pd 30wt.%/C > Pt50wt.%/C > 27wt.%Pt-13wt.%Ru/C. A large oxidation current for formic acid was found at a low overpotential on the palladium electrocatalysts. These results indicate that formic acid is mainly oxidized through a dehydrogenation reaction. For the oxidation of 2-propanol and methanol, palladium was not effective, and 27wt.%Pt-13wt.%Ru/C showed the best oxidation activity.
- 社団法人 電気学会の論文
- 2008-12-01
著者
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Ota Ken-ichiro
Department Of Energy & Safety Engineering Faculty Of Engineering Yokohama National University
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Ota Ken-ichiro
Yokohama National University
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KAMIYA Nobuyuki
Yokohama National University
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LIU Yan
Yokohama National University
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MITSUSHIMA Shigenori
Yokohama National University
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TSUTSUMI Yasuyuki
Electric Power Development Co., Ltd.
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OGAWA Naoya
Electric Power Development Co., Ltd.
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KON Norihiro
Department of Biomolecular Functional Engineering, Faculty of Engineering, Ibaraki University
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EGUCHI Mika
Department of Biomolecular Functional Engineering, Faculty of Engineering, Ibaraki University
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Kamiya N
Yokohama National Univ. Kanagawa‐ken
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Ogawa Naoya
Electric Power Development Co. Ltd.
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Tsutsumi Yasuyuki
Electric Power Development Co. Ltd.
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Eguchi Mika
Department Of Biomolecular Functional Engineering Faculty Of Engineering Ibaraki University
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Kon Norihiro
Department Of Biomolecular Functional Engineering Faculty Of Engineering Ibaraki University
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Ota Ken-ichiro
Yokohama National University Graduate School Of Engineering
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Mitsushima Shigenori
Yokohama National University Graduate School Of Engineering
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Ota K
Yokohama National University Graduate School Of Engineering
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Ota K
Green Hydrogen Research Center Yokohama National University
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