H2 production from ammonia decomposition with Mo2N catalyst driven by dielectric barrier discharge plasma

H2 production from ammonia decomposition with Mo2N catalyst driven by dielectric barrier discharge plasma

Dielectric barrier discharge (DBD) plasma-assisted ammonia decomposition reaction was investigated to produce carbon-free hydrogen for fuel cell applications. Mo2N catalyst was synthesized and applied for catalytic ammonia decomposition in different reaction modes. The synergistic effect of using Mo...

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Bibliographic Details
Published in:International journal of hydrogen energy Vol. 49; pp. 1375 - 1385
Main Authors: Wang, Zhijun, Zhang, Huazhou, Ye, Zongbiao, He, Ge, Liao, Che, Deng, Jiyou, Lei, Guangjiu, Zheng, Guoyao, Zhang, Kun, Gou, Fujun, Mao, Xinchun
Format: Journal Article
Language:English
Published: Elsevier Ltd 02-01-2024
Subjects:
Ammonia decomposition
Dielectric barrier discharge plasma
Hydrogen production
Molybdenum nitride
Plasma catalysis
Molybdenum nitride
Ammonia decomposition
Dielectric barrier discharge plasma
Plasma catalysis
Hydrogen production
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Summary:Dielectric barrier discharge (DBD) plasma-assisted ammonia decomposition reaction was investigated to produce carbon-free hydrogen for fuel cell applications. Mo2N catalyst was synthesized and applied for catalytic ammonia decomposition in different reaction modes. The synergistic effect of using Mo2N catalyst in combination with DBD plasma resulted in near complete conversion of NH3 decomposition at specific energy input (SEI) of 39.6 kJ L−1, giving an energy efficiency of 6.1 mol·kWh−1 for H2 production. The particle size of Mo2N catalyst was discovered to affect the plasma-catalytic performance for NH3 decomposition, with Mo2N-powder catalyst showing higher reactivity compared with Mo2N-particle catalyst. The plasma diagnostic results showed that, compared to the filamentary discharge with Mo2N-particle catalyst, the Mo2N-powder catalyst packing lead to a predominant surface discharge; such localized surface discharges might contribute to a facile transportation of reactive species from the plasma phase to the catalyst surface, thus leading to higher plasma-catalytic performance. •Plasma driven NH3 decomposition with Mo2N catalyst to produce hydrogen.•Plasma reduces NH3 full conversion temperature by > 100 °C compared to catalysis.•Mo2N catalyst size affects the plasma-catalytic performance.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2023.06.173