In Situ Exsolved CoFeRu Alloy Decorated Perovskite as An Anode Catalyst Layer for High-Performance Direct-Ammonia Protonic Ceramic Fuel Cells

Mingzhuang Liang; Yufei Song; Baocheng Xiong; Dongliang Liu; Daxiang Xue; Longyun Shen; Kanghua Shi; Yixiao Song; Jingwei Li; Qiang Niu; Meigui Xu; Francesco Ciucci; Wei Zhou; Zongping Shao

doi:10.1002/adfm.202408756

In Situ Exsolved CoFeRu Alloy Decorated Perovskite as An Anode Catalyst Layer for High-Performance Direct-Ammonia Protonic Ceramic Fuel Cells

Mingzhuang Liang, Yufei Song, Baocheng Xiong, Dongliang Liu, Daxiang Xue, Longyun Shen, Kanghua Shi, Yixiao Song, Jingwei Li, Qiang Niu, Meigui Xu, Francesco Ciucci, Wei Zhou, Zongping Shao

COLLEGE OF CHEMICAL ENGINEERING

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

5 Scopus citations

Abstract

Direct-ammonia proton ceramic fuel cell (DA-PCFC) is a promising clean energy technology because ammonia (NH₃) is easier to store, transport, and handle than hydrogen. However, NH₃ decomposition efficiency is unsatisfactory, and the anti-sintering resistance of conventional Ni-based ceramic anodes has limited the large-scale application of DA-PCFC technology. Herein, Pr_0.6Sr_0.4(Co_0.2Fe_0.8)_0.85Ru_0.15O_3-δ (PSCFR15), a novel anode catalyst layer (ACL) material is developed. PSCFR15 is treated under a reducing atmosphere to form a composite with CoFeRu alloy nanoparticles. Density functional theory simulations reveal that Ru modification in the CoFe alloy promotes nitrogen desorption during ammonia decomposition reaction, thereby boosting ammonia decomposition efficiency. As a result, DA-PCFC with PSCFR15 ACL can achieve superior peak power density compared to bare DA-PCFC operated with H₂ and NH₃ fuels. Furthermore, the ACL also reduces the direct contact between the Ni-based ceramic anode and the NH₃ fuel, then suppressing Ni sintering, and enhancing the durability of the DA-PCFC.

Original language	English
Article number	2408756
Journal	Advanced Functional Materials
Volume	34
Issue number	48
DOIs	https://doi.org/10.1002/adfm.202408756
State	Published - 26 Nov 2024

Keywords

Direct-ammonia proton ceramic fuel cell
alloy catalysts
ammonia decomposition
anode catalyst layer
perovskite

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Liang, M., Song, Y., Xiong, B., Liu, D., Xue, D., Shen, L., Shi, K., Song, Y., Li, J., Niu, Q., Xu, M., Ciucci, F., Zhou, W., & Shao, Z. (2024). In Situ Exsolved CoFeRu Alloy Decorated Perovskite as An Anode Catalyst Layer for High-Performance Direct-Ammonia Protonic Ceramic Fuel Cells. Advanced Functional Materials, 34(48), Article 2408756. https://doi.org/10.1002/adfm.202408756

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title = "In Situ Exsolved CoFeRu Alloy Decorated Perovskite as An Anode Catalyst Layer for High-Performance Direct-Ammonia Protonic Ceramic Fuel Cells",

abstract = "Direct-ammonia proton ceramic fuel cell (DA-PCFC) is a promising clean energy technology because ammonia (NH3) is easier to store, transport, and handle than hydrogen. However, NH3 decomposition efficiency is unsatisfactory, and the anti-sintering resistance of conventional Ni-based ceramic anodes has limited the large-scale application of DA-PCFC technology. Herein, Pr0.6Sr0.4(Co0.2Fe0.8)0.85Ru0.15O3-δ (PSCFR15), a novel anode catalyst layer (ACL) material is developed. PSCFR15 is treated under a reducing atmosphere to form a composite with CoFeRu alloy nanoparticles. Density functional theory simulations reveal that Ru modification in the CoFe alloy promotes nitrogen desorption during ammonia decomposition reaction, thereby boosting ammonia decomposition efficiency. As a result, DA-PCFC with PSCFR15 ACL can achieve superior peak power density compared to bare DA-PCFC operated with H2 and NH3 fuels. Furthermore, the ACL also reduces the direct contact between the Ni-based ceramic anode and the NH3 fuel, then suppressing Ni sintering, and enhancing the durability of the DA-PCFC.",

keywords = "Direct-ammonia proton ceramic fuel cell, alloy catalysts, ammonia decomposition, anode catalyst layer, perovskite",

author = "Mingzhuang Liang and Yufei Song and Baocheng Xiong and Dongliang Liu and Daxiang Xue and Longyun Shen and Kanghua Shi and Yixiao Song and Jingwei Li and Qiang Niu and Meigui Xu and Francesco Ciucci and Wei Zhou and Zongping Shao",

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year = "2024",

month = nov,

day = "26",

doi = "10.1002/adfm.202408756",

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volume = "34",

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T1 - In Situ Exsolved CoFeRu Alloy Decorated Perovskite as An Anode Catalyst Layer for High-Performance Direct-Ammonia Protonic Ceramic Fuel Cells

AU - Liang, Mingzhuang

AU - Song, Yufei

AU - Xiong, Baocheng

AU - Liu, Dongliang

AU - Xue, Daxiang

AU - Shen, Longyun

AU - Shi, Kanghua

AU - Song, Yixiao

AU - Li, Jingwei

AU - Niu, Qiang

AU - Xu, Meigui

AU - Ciucci, Francesco

AU - Zhou, Wei

AU - Shao, Zongping

PY - 2024/11/26

Y1 - 2024/11/26

N2 - Direct-ammonia proton ceramic fuel cell (DA-PCFC) is a promising clean energy technology because ammonia (NH3) is easier to store, transport, and handle than hydrogen. However, NH3 decomposition efficiency is unsatisfactory, and the anti-sintering resistance of conventional Ni-based ceramic anodes has limited the large-scale application of DA-PCFC technology. Herein, Pr0.6Sr0.4(Co0.2Fe0.8)0.85Ru0.15O3-δ (PSCFR15), a novel anode catalyst layer (ACL) material is developed. PSCFR15 is treated under a reducing atmosphere to form a composite with CoFeRu alloy nanoparticles. Density functional theory simulations reveal that Ru modification in the CoFe alloy promotes nitrogen desorption during ammonia decomposition reaction, thereby boosting ammonia decomposition efficiency. As a result, DA-PCFC with PSCFR15 ACL can achieve superior peak power density compared to bare DA-PCFC operated with H2 and NH3 fuels. Furthermore, the ACL also reduces the direct contact between the Ni-based ceramic anode and the NH3 fuel, then suppressing Ni sintering, and enhancing the durability of the DA-PCFC.

AB - Direct-ammonia proton ceramic fuel cell (DA-PCFC) is a promising clean energy technology because ammonia (NH3) is easier to store, transport, and handle than hydrogen. However, NH3 decomposition efficiency is unsatisfactory, and the anti-sintering resistance of conventional Ni-based ceramic anodes has limited the large-scale application of DA-PCFC technology. Herein, Pr0.6Sr0.4(Co0.2Fe0.8)0.85Ru0.15O3-δ (PSCFR15), a novel anode catalyst layer (ACL) material is developed. PSCFR15 is treated under a reducing atmosphere to form a composite with CoFeRu alloy nanoparticles. Density functional theory simulations reveal that Ru modification in the CoFe alloy promotes nitrogen desorption during ammonia decomposition reaction, thereby boosting ammonia decomposition efficiency. As a result, DA-PCFC with PSCFR15 ACL can achieve superior peak power density compared to bare DA-PCFC operated with H2 and NH3 fuels. Furthermore, the ACL also reduces the direct contact between the Ni-based ceramic anode and the NH3 fuel, then suppressing Ni sintering, and enhancing the durability of the DA-PCFC.

KW - Direct-ammonia proton ceramic fuel cell

KW - alloy catalysts

KW - ammonia decomposition

KW - anode catalyst layer

KW - perovskite

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U2 - 10.1002/adfm.202408756

DO - 10.1002/adfm.202408756

M3 - 文章

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SN - 1616-301X

VL - 34

JO - Advanced Functional Materials

JF - Advanced Functional Materials

IS - 48

M1 - 2408756

ER -

In Situ Exsolved CoFeRu Alloy Decorated Perovskite as An Anode Catalyst Layer for High-Performance Direct-Ammonia Protonic Ceramic Fuel Cells

Abstract

Keywords

UN SDGs

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