Rational design of superior, coking-resistant, nickel-based anodes through tailoring interfacial reactions for solid oxide fuel cells operated on methane fuel
The reaction between a Ni−Y2O3‐stabilized ZrO2 (Ni‐YSZ) cermet anode and La5.4WO12−δ (LW) during cell fabrication is utilized to reduce carbon deposition in solid oxide fuel cells operated on methane fuel. The effect of the phase reactions on the microstructure, electrical conductivity, chemical int...
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sg-ntu-dr.10356-1417792020-06-10T09:22:29Z Rational design of superior, coking-resistant, nickel-based anodes through tailoring interfacial reactions for solid oxide fuel cells operated on methane fuel Qu, Jifa Wang, Wei Chen, Yubo Li, Haidong Zhong, Yijun Yang, Guangming Zhou, Wei Shao, Zongping School of Materials Science and Engineering Engineering::Materials Carbon Doping The reaction between a Ni−Y2O3‐stabilized ZrO2 (Ni‐YSZ) cermet anode and La5.4WO12−δ (LW) during cell fabrication is utilized to reduce carbon deposition in solid oxide fuel cells operated on methane fuel. The effect of the phase reactions on the microstructure, electrical conductivity, chemical interactions, and coking resistance of the anodes are systematically investigated. Nix Wy and La‐doped YSZ are formed by phase reactions and the synergistic effect between them increases the coking resistance dramatically. 2 wt % is demonstrated to be the optimal amount of LW to modify Ni‐YSZ to achieve best coking resistance. The cell with Ni‐YSZ‐2 wt % LW anode demonstrates a superior peak power density of 943 mW cm−2 at 800 °C with humidified methane as fuel, which is 10 % higher than that of Ni‐YSZ (859 mW cm−2). Furthermore, the cell is stable for 200 h in methane fuel with no clear performance degradation while the cell with unmodified anode fails after 0.5 h's operation. In summary, we provide a new way to rationally design Ni‐based cermet anode with high electrocatalytic activity and excellent coking resistance. 2020-06-10T09:22:29Z 2020-06-10T09:22:29Z 2018 Journal Article Qu, J., Wang, W., Chen, Y., Li, H., Zhong, Y., Yang, G., . . . Shao, Z. (2018). Rational design of superior, coking-resistant, nickel-based anodes through tailoring interfacial reactions for solid oxide fuel cells operated on methane fuel. ChemSusChem, 11(18), 3112-3119. doi:10.1002/cssc.201801539 1864-5631 https://hdl.handle.net/10356/141779 10.1002/cssc.201801539 30039570 2-s2.0-85052616389 18 11 3112 3119 en ChemSusChem © 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim. All rights reserved. |
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Engineering::Materials Carbon Doping Qu, Jifa Wang, Wei Chen, Yubo Li, Haidong Zhong, Yijun Yang, Guangming Zhou, Wei Shao, Zongping Rational design of superior, coking-resistant, nickel-based anodes through tailoring interfacial reactions for solid oxide fuel cells operated on methane fuel |
| description |
The reaction between a Ni−Y2O3‐stabilized ZrO2 (Ni‐YSZ) cermet anode and La5.4WO12−δ (LW) during cell fabrication is utilized to reduce carbon deposition in solid oxide fuel cells operated on methane fuel. The effect of the phase reactions on the microstructure, electrical conductivity, chemical interactions, and coking resistance of the anodes are systematically investigated. Nix Wy and La‐doped YSZ are formed by phase reactions and the synergistic effect between them increases the coking resistance dramatically. 2 wt % is demonstrated to be the optimal amount of LW to modify Ni‐YSZ to achieve best coking resistance. The cell with Ni‐YSZ‐2 wt % LW anode demonstrates a superior peak power density of 943 mW cm−2 at 800 °C with humidified methane as fuel, which is 10 % higher than that of Ni‐YSZ (859 mW cm−2). Furthermore, the cell is stable for 200 h in methane fuel with no clear performance degradation while the cell with unmodified anode fails after 0.5 h's operation. In summary, we provide a new way to rationally design Ni‐based cermet anode with high electrocatalytic activity and excellent coking resistance. |
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School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Qu, Jifa Wang, Wei Chen, Yubo Li, Haidong Zhong, Yijun Yang, Guangming Zhou, Wei Shao, Zongping |
| format |
Article |
| author |
Qu, Jifa Wang, Wei Chen, Yubo Li, Haidong Zhong, Yijun Yang, Guangming Zhou, Wei Shao, Zongping |
| author_sort |
Qu, Jifa |
| title |
Rational design of superior, coking-resistant, nickel-based anodes through tailoring interfacial reactions for solid oxide fuel cells operated on methane fuel |
| title_short |
Rational design of superior, coking-resistant, nickel-based anodes through tailoring interfacial reactions for solid oxide fuel cells operated on methane fuel |
| title_full |
Rational design of superior, coking-resistant, nickel-based anodes through tailoring interfacial reactions for solid oxide fuel cells operated on methane fuel |
| title_fullStr |
Rational design of superior, coking-resistant, nickel-based anodes through tailoring interfacial reactions for solid oxide fuel cells operated on methane fuel |
| title_full_unstemmed |
Rational design of superior, coking-resistant, nickel-based anodes through tailoring interfacial reactions for solid oxide fuel cells operated on methane fuel |
| title_sort |
rational design of superior, coking-resistant, nickel-based anodes through tailoring interfacial reactions for solid oxide fuel cells operated on methane fuel |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/141779 |
| _version_ |
1681058863609020416 |