Solar-driven hydrogen generation coupled with urea electrolysis by an oxygen vacancy-rich catalyst
Urea, an environmental pollutant for both soil and water, is widely present in wastewater. On the other hand, a strategy utilizing renewable electricity to decrease the cost of green hydrogen, which holds the key to a sustainable energy future, is promising but challenging. Gas crossover that gen...
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sg-ntu-dr.10356-1548482022-01-17T06:15:18Z Solar-driven hydrogen generation coupled with urea electrolysis by an oxygen vacancy-rich catalyst Yao, Mengqi Ge, Junyu Sun, Baolong Hu, Jun Koh, See Wee Zhao, Yunxing Fei, Jipeng Sun, Zixu Hong, Wei Chen, Zhong Hu, Wencheng Li, Hong School of Mechanical and Aerospace Engineering School of Materials Science and Engineering School of Electrical and Electronic Engineering Centre for Micro-/Nano-electronics (NOVITAS) CNRS International NTU THALES Research Alliances Engineering::Chemical engineering::Industrial electrochemistry Solar-to-Hydrogen Waste−to−Value Plasma Engineering Green Hydrogen Urea Oxidation Urea, an environmental pollutant for both soil and water, is widely present in wastewater. On the other hand, a strategy utilizing renewable electricity to decrease the cost of green hydrogen, which holds the key to a sustainable energy future, is promising but challenging. Gas crossover that generates explosive hydrogen–oxygen mixture becomes very serious with intermittent renewable power source (partial load issue). Herein, we address these issues in one device, i.e., a hybrid electrolyzer where water oxidation that produces oxygen is replaced by urea oxidation which generates inert gases. A self-supported electrocatalyst of nitrogen-doped nickel-iron oxyhydroxide derived from waste rusty iron foam was synthesized via an in situ ‘waste-to-value’ synthetic route followed by an ammonia/argon plasma treatment, which reconstructed the surface of the catalyst to a 3D nanosheet-like porous network with abundant oxygen vacancies. The as-prepared catalyst showed a small potential of 1.45 V vs. RHE at 500 mA cm-2 for urea oxidation reaction. Overall water-urea electrolysis only required 1.58 V to deliver 100 mA cm-2, which was 0.33 V less than that in urea-free water splitting, and thus lowered the overall energy consumption by 17.3%. Without oxygen evolution, the hybrid electrolysis does not suffer from the safety hazard caused by explosive hydrogen–oxygen mixture. We demonstrate the safe production of green hydrogen (3.1% oxygen in the gaseous product) in the hybrid electrolysis powered by solar energy via a photovoltaic panel. Our work provides a method to address the urea-caused environmental issues and simultaneously generate green hydrogen safely using solar energy. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) Nanyang Technological University Accepted version This work is supported by Nanyang Technological University under NAP award (M408050000), A*STAR Science & Engineering Research Council AME IRG funding (A1983c0029) and Singapore Ministry of Education Tier 1 program (2018−T1−001−051). M.Y., B.S. and W.H. acknowledge the financial support from the National Natural Science Foundation of China (Grant No. 51902041) and J.H. acknowledges the National Natural Science Foundation of China (Grant No. 21676216). M.Y. is grateful for the financial support from the program of China Scholarships Council (No. 201906070049). 2022-01-17T06:15:17Z 2022-01-17T06:15:17Z 2021 Journal Article Yao, M., Ge, J., Sun, B., Hu, J., Koh, S. W., Zhao, Y., Fei, J., Sun, Z., Hong, W., Chen, Z., Hu, W. & Li, H. (2021). Solar-driven hydrogen generation coupled with urea electrolysis by an oxygen vacancy-rich catalyst. Chemical Engineering Journal, 414, 128753-. https://dx.doi.org/10.1016/j.cej.2021.128753 1385-8947 https://hdl.handle.net/10356/154848 10.1016/j.cej.2021.128753 414 128753 en M408050000 A1983c0029 2018-T1-001-051 Chemical Engineering Journal © 2021 Elsevier B.V. All rights reserved. This paper was published in Chemical Engineering Journal and is made available with permission of Elsevier B.V. application/pdf |
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Engineering::Chemical engineering::Industrial electrochemistry Solar-to-Hydrogen Waste−to−Value Plasma Engineering Green Hydrogen Urea Oxidation |
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Engineering::Chemical engineering::Industrial electrochemistry Solar-to-Hydrogen Waste−to−Value Plasma Engineering Green Hydrogen Urea Oxidation Yao, Mengqi Ge, Junyu Sun, Baolong Hu, Jun Koh, See Wee Zhao, Yunxing Fei, Jipeng Sun, Zixu Hong, Wei Chen, Zhong Hu, Wencheng Li, Hong Solar-driven hydrogen generation coupled with urea electrolysis by an oxygen vacancy-rich catalyst |
| description |
Urea, an environmental pollutant for both soil and water, is widely present in
wastewater. On the other hand, a strategy utilizing renewable electricity to decrease the cost
of green hydrogen, which holds the key to a sustainable energy future, is promising but
challenging. Gas crossover that generates explosive hydrogen–oxygen mixture becomes very
serious with intermittent renewable power source (partial load issue). Herein, we address
these issues in one device, i.e., a hybrid electrolyzer where water oxidation that produces
oxygen is replaced by urea oxidation which generates inert gases. A self-supported
electrocatalyst of nitrogen-doped nickel-iron oxyhydroxide derived from waste rusty iron
foam was synthesized via an in situ ‘waste-to-value’ synthetic route followed by an
ammonia/argon plasma treatment, which reconstructed the surface of the catalyst to a 3D
nanosheet-like porous network with abundant oxygen vacancies. The as-prepared catalyst
showed a small potential of 1.45 V vs. RHE at 500 mA cm-2 for urea oxidation reaction.
Overall water-urea electrolysis only required 1.58 V to deliver 100 mA cm-2, which was 0.33
V less than that in urea-free water splitting, and thus lowered the overall energy consumption
by 17.3%. Without oxygen evolution, the hybrid electrolysis does not suffer from the safety
hazard caused by explosive hydrogen–oxygen mixture. We demonstrate the safe production of
green hydrogen (3.1% oxygen in the gaseous product) in the hybrid electrolysis powered by
solar energy via a photovoltaic panel. Our work provides a method to address the urea-caused
environmental issues and simultaneously generate green hydrogen safely using solar energy. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Yao, Mengqi Ge, Junyu Sun, Baolong Hu, Jun Koh, See Wee Zhao, Yunxing Fei, Jipeng Sun, Zixu Hong, Wei Chen, Zhong Hu, Wencheng Li, Hong |
| format |
Article |
| author |
Yao, Mengqi Ge, Junyu Sun, Baolong Hu, Jun Koh, See Wee Zhao, Yunxing Fei, Jipeng Sun, Zixu Hong, Wei Chen, Zhong Hu, Wencheng Li, Hong |
| author_sort |
Yao, Mengqi |
| title |
Solar-driven hydrogen generation coupled with urea electrolysis by an oxygen vacancy-rich catalyst |
| title_short |
Solar-driven hydrogen generation coupled with urea electrolysis by an oxygen vacancy-rich catalyst |
| title_full |
Solar-driven hydrogen generation coupled with urea electrolysis by an oxygen vacancy-rich catalyst |
| title_fullStr |
Solar-driven hydrogen generation coupled with urea electrolysis by an oxygen vacancy-rich catalyst |
| title_full_unstemmed |
Solar-driven hydrogen generation coupled with urea electrolysis by an oxygen vacancy-rich catalyst |
| title_sort |
solar-driven hydrogen generation coupled with urea electrolysis by an oxygen vacancy-rich catalyst |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/154848 |
| _version_ |
1722355357267787776 |