1-Naphthol induced Pt3Ag nanocorals as bifunctional cathode and anode catalysts of direct formic acid fuel cells
Developing highly efficient bifunctional cathode and anode electrocatalysts is very important for the large-scale application of direct formic acid fuel cells. However, the high-cost and poor CO-tolerance ability of the most commonly used Pt greatly block this process. To increase the utilization ef...
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sg-ntu-dr.10356-1513452021-06-22T09:08:54Z 1-Naphthol induced Pt3Ag nanocorals as bifunctional cathode and anode catalysts of direct formic acid fuel cells Jiang, Xian Liu, Yang Wang, Jiaxin Wang, Yufei Xiong, Yuexin Liu, Qun Li, Naixu Zhou, Jiancheng Fu, Gengtao Sun, Dongmei Tang, Yawen School of Chemical and Biomedical Engineering Engineering::Chemical engineering Pt3Ag Alloy Nanocorals Developing highly efficient bifunctional cathode and anode electrocatalysts is very important for the large-scale application of direct formic acid fuel cells. However, the high-cost and poor CO-tolerance ability of the most commonly used Pt greatly block this process. To increase the utilization efficiency and extend bifunctional properties of precious Pt, herein, coral-like Pt3Ag nanocrystals are developed as an excellent bifunctional electrocatalyst through a facile one-pot solvothermal method. The formation mechanism of Pt3Ag nanocorals has been elaborated well via a series of control experiments. It is proved that 1-naphthol serving as a guiding surfactant plays a key role in the formation of high-quality nanocorals. Thanks to the unique coral-like structure and alloy effects, the developed Pt3Ag nanocorals present significantly enhanced electrocatalytic properties (including activity, stability and CO-tolerance ability) towards both the cathodic oxygen reduction and anodic formic acid oxidation, as compared with those of commercial Pt black and Pt-based nanoparticles. The present synthetic method can also be extended to fabricate other bimetallic electrocatalysts with unique morphology and structure. 2021-06-22T09:08:53Z 2021-06-22T09:08:53Z 2019 Journal Article Jiang, X., Liu, Y., Wang, J., Wang, Y., Xiong, Y., Liu, Q., Li, N., Zhou, J., Fu, G., Sun, D. & Tang, Y. (2019). 1-Naphthol induced Pt3Ag nanocorals as bifunctional cathode and anode catalysts of direct formic acid fuel cells. Nano Research, 12(2), 323-329. https://dx.doi.org/10.1007/s12274-018-2218-2 1998-0124 https://hdl.handle.net/10356/151345 10.1007/s12274-018-2218-2 2-s2.0-85055554800 2 12 323 329 en Nano Research © 2018 Tsinghua University Press and Springer-Verlag GmbH Germany, part of Springer Nature. All rights reserved. |
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Engineering::Chemical engineering Pt3Ag Alloy Nanocorals Jiang, Xian Liu, Yang Wang, Jiaxin Wang, Yufei Xiong, Yuexin Liu, Qun Li, Naixu Zhou, Jiancheng Fu, Gengtao Sun, Dongmei Tang, Yawen 1-Naphthol induced Pt3Ag nanocorals as bifunctional cathode and anode catalysts of direct formic acid fuel cells |
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Developing highly efficient bifunctional cathode and anode electrocatalysts is very important for the large-scale application of direct formic acid fuel cells. However, the high-cost and poor CO-tolerance ability of the most commonly used Pt greatly block this process. To increase the utilization efficiency and extend bifunctional properties of precious Pt, herein, coral-like Pt3Ag nanocrystals are developed as an excellent bifunctional electrocatalyst through a facile one-pot solvothermal method. The formation mechanism of Pt3Ag nanocorals has been elaborated well via a series of control experiments. It is proved that 1-naphthol serving as a guiding surfactant plays a key role in the formation of high-quality nanocorals. Thanks to the unique coral-like structure and alloy effects, the developed Pt3Ag nanocorals present significantly enhanced electrocatalytic properties (including activity, stability and CO-tolerance ability) towards both the cathodic oxygen reduction and anodic formic acid oxidation, as compared with those of commercial Pt black and Pt-based nanoparticles. The present synthetic method can also be extended to fabricate other bimetallic electrocatalysts with unique morphology and structure. |
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School of Chemical and Biomedical Engineering |
| author_facet |
School of Chemical and Biomedical Engineering Jiang, Xian Liu, Yang Wang, Jiaxin Wang, Yufei Xiong, Yuexin Liu, Qun Li, Naixu Zhou, Jiancheng Fu, Gengtao Sun, Dongmei Tang, Yawen |
| format |
Article |
| author |
Jiang, Xian Liu, Yang Wang, Jiaxin Wang, Yufei Xiong, Yuexin Liu, Qun Li, Naixu Zhou, Jiancheng Fu, Gengtao Sun, Dongmei Tang, Yawen |
| author_sort |
Jiang, Xian |
| title |
1-Naphthol induced Pt3Ag nanocorals as bifunctional cathode and anode catalysts of direct formic acid fuel cells |
| title_short |
1-Naphthol induced Pt3Ag nanocorals as bifunctional cathode and anode catalysts of direct formic acid fuel cells |
| title_full |
1-Naphthol induced Pt3Ag nanocorals as bifunctional cathode and anode catalysts of direct formic acid fuel cells |
| title_fullStr |
1-Naphthol induced Pt3Ag nanocorals as bifunctional cathode and anode catalysts of direct formic acid fuel cells |
| title_full_unstemmed |
1-Naphthol induced Pt3Ag nanocorals as bifunctional cathode and anode catalysts of direct formic acid fuel cells |
| title_sort |
1-naphthol induced pt3ag nanocorals as bifunctional cathode and anode catalysts of direct formic acid fuel cells |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/151345 |
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1703971191198318592 |