Turning water from a hindrance to the promotor of preferential electrochemical nitrogen reduction
Electrochemical nitrogen reduction reaction (NRR) offers sustainable ammonia production but suffers from poor performance owing to favorable water electrolysis. Recent designs achieve better efficiency by eradicating water but do not leverage on water as a readily available NRR proton source. Herein...
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sg-ntu-dr.10356-1609442022-08-08T05:31:11Z Turning water from a hindrance to the promotor of preferential electrochemical nitrogen reduction Koh, Charlynn Sher Lin Lee, Hiang Kwee Sim, Howard Yi Fan Han, Xuemei Phan-Quang, Gia Chuong Ling, Xing Yi School of Physical and Mathematical Sciences Science::Chemistry Hydrophobic Modification Nitrogen Adsorption Electrochemical nitrogen reduction reaction (NRR) offers sustainable ammonia production but suffers from poor performance owing to favorable water electrolysis. Recent designs achieve better efficiency by eradicating water but do not leverage on water as a readily available NRR proton source. Herein, we design a hydrophobic oleylamine-functionalized zeolitic-imidazolate framework coated over the electrocatalyst to achieve >18% NRR efficiency in the presence of water, an approximately fourfold boost compared to that without water. Our strategy kinetically regulates water availability at the electrocatalyst surface, suppresses direct water adsorption/electrolysis, and promotes preferential nitrogen adsorption to achieve water-assisted NRR. Conversely, control systems without hydrophobic modification experience a drastic decrease in efficiencies (<3%) upon water addition. In situ surface-enhanced Raman scattering investigation reveals that our hydrophobic system's ability in suppressing water accessibility to the electrocatalyst is the key to transform water from a hindrance to an NRR promotor. Our universal design is a paradigm shift from current approaches to achieve sustainable air-to-ammonia electrosynthesis. Ministry of Education (MOE) X.Y.L. thanks the financial support from the Singapore Ministry of Education, Tier 1 (RG11/18) and Tier 2 (MOE2016-T2-1-043) grants, 2022-08-08T05:31:11Z 2022-08-08T05:31:11Z 2020 Journal Article Koh, C. S. L., Lee, H. K., Sim, H. Y. F., Han, X., Phan-Quang, G. C. & Ling, X. Y. (2020). Turning water from a hindrance to the promotor of preferential electrochemical nitrogen reduction. Chemistry of Materials, 32(4), 1674-1683. https://dx.doi.org/10.1021/acs.chemmater.9b05313 0897-4756 https://hdl.handle.net/10356/160944 10.1021/acs.chemmater.9b05313 2-s2.0-85081118199 4 32 1674 1683 en RG11/18 MOE2016-T2-1-043 Chemistry of Materials © 2020 American Chemical Society. All rights reserved. |
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Science::Chemistry Hydrophobic Modification Nitrogen Adsorption |
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Science::Chemistry Hydrophobic Modification Nitrogen Adsorption Koh, Charlynn Sher Lin Lee, Hiang Kwee Sim, Howard Yi Fan Han, Xuemei Phan-Quang, Gia Chuong Ling, Xing Yi Turning water from a hindrance to the promotor of preferential electrochemical nitrogen reduction |
| description |
Electrochemical nitrogen reduction reaction (NRR) offers sustainable ammonia production but suffers from poor performance owing to favorable water electrolysis. Recent designs achieve better efficiency by eradicating water but do not leverage on water as a readily available NRR proton source. Herein, we design a hydrophobic oleylamine-functionalized zeolitic-imidazolate framework coated over the electrocatalyst to achieve >18% NRR efficiency in the presence of water, an approximately fourfold boost compared to that without water. Our strategy kinetically regulates water availability at the electrocatalyst surface, suppresses direct water adsorption/electrolysis, and promotes preferential nitrogen adsorption to achieve water-assisted NRR. Conversely, control systems without hydrophobic modification experience a drastic decrease in efficiencies (<3%) upon water addition. In situ surface-enhanced Raman scattering investigation reveals that our hydrophobic system's ability in suppressing water accessibility to the electrocatalyst is the key to transform water from a hindrance to an NRR promotor. Our universal design is a paradigm shift from current approaches to achieve sustainable air-to-ammonia electrosynthesis. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Koh, Charlynn Sher Lin Lee, Hiang Kwee Sim, Howard Yi Fan Han, Xuemei Phan-Quang, Gia Chuong Ling, Xing Yi |
| format |
Article |
| author |
Koh, Charlynn Sher Lin Lee, Hiang Kwee Sim, Howard Yi Fan Han, Xuemei Phan-Quang, Gia Chuong Ling, Xing Yi |
| author_sort |
Koh, Charlynn Sher Lin |
| title |
Turning water from a hindrance to the promotor of preferential electrochemical nitrogen reduction |
| title_short |
Turning water from a hindrance to the promotor of preferential electrochemical nitrogen reduction |
| title_full |
Turning water from a hindrance to the promotor of preferential electrochemical nitrogen reduction |
| title_fullStr |
Turning water from a hindrance to the promotor of preferential electrochemical nitrogen reduction |
| title_full_unstemmed |
Turning water from a hindrance to the promotor of preferential electrochemical nitrogen reduction |
| title_sort |
turning water from a hindrance to the promotor of preferential electrochemical nitrogen reduction |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/160944 |
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1743119481885949952 |