Surface activation of atomically thin metal nitride by confined nanoclusters to trigger pH-universal hydrogen evolution
Transition metal nitrides hold great potential for electrochemical conversion by virtue of metal-like electrical conductivity and robust electrochemical stability. Their applications, however, are still limited due to the sluggish kinetics stemming from the unfavorable surface electron properties. H...
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sg-ntu-dr.10356-1713062023-10-20T05:22:45Z Surface activation of atomically thin metal nitride by confined nanoclusters to trigger pH-universal hydrogen evolution Do, Viet-Hung Prabhu, P. Li, Yinghao Xie, Wenjie Kidkhunthod, Pinit Wang, Guangzhao Wang, Xin Lee, Jong-Min School of Chemistry, Chemical Engineering and Biotechnology Interdisciplinary Graduate School (IGS) Energy Research Institute @ NTU (ERI@N) Engineering::Chemical engineering Nanosheet Electrocatalyst Transition metal nitrides hold great potential for electrochemical conversion by virtue of metal-like electrical conductivity and robust electrochemical stability. Their applications, however, are still limited due to the sluggish kinetics stemming from the unfavorable surface electron properties. Herein, we demonstrate that the confinement of atomically thin Os nanoclusters onto 2D δ-MoN can favorably optimize the surface electron configurations, thereby boosting the material's catalytic performance. MoN-5% Os catalyst with optimal Os loading exhibits high catalytic performance, surpassing that of commercial Pt/C. The enhanced hydrogen evolution performance is attributed to (1) the unique 2D atomically thin nanoarchitecture exposing abundant active sites and (2) the strong electronic interaction between Os nanoclusters and δ-MoN nanosheets, which favorably modulates the surface microenvironment. Theoretical investigation reveals that the confined Os nanoclusters function as surface activators, efficiently modulating the electron properties of MoN, thereby accelerating the sluggish water adsorption and dissociation processes and triggering favorable hydrogen adsorption. Ministry of Education (MOE) This work was financially supported by the AcRF Tier 1 (grant RG105/19) provided by the Ministry of Education in Singapore. X.W. greatly acknowledge the startup grant by City University of Hong Kong (grant no. 9020005) and Hong Kong Branch of National Precious Metals Material Engineering Research Center - ITC Fund. 2023-10-20T05:22:45Z 2023-10-20T05:22:45Z 2023 Journal Article Do, V., Prabhu, P., Li, Y., Xie, W., Kidkhunthod, P., Wang, G., Wang, X. & Lee, J. (2023). Surface activation of atomically thin metal nitride by confined nanoclusters to trigger pH-universal hydrogen evolution. Joule, 7(9), 2118-2134. https://dx.doi.org/10.1016/j.joule.2023.07.009 2542-4351 https://hdl.handle.net/10356/171306 10.1016/j.joule.2023.07.009 2-s2.0-85170095364 9 7 2118 2134 en RG105/19 Joule © 2023 Elsevier Inc. All rights reserved. |
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Engineering::Chemical engineering Nanosheet Electrocatalyst Do, Viet-Hung Prabhu, P. Li, Yinghao Xie, Wenjie Kidkhunthod, Pinit Wang, Guangzhao Wang, Xin Lee, Jong-Min Surface activation of atomically thin metal nitride by confined nanoclusters to trigger pH-universal hydrogen evolution |
| description |
Transition metal nitrides hold great potential for electrochemical conversion by virtue of metal-like electrical conductivity and robust electrochemical stability. Their applications, however, are still limited due to the sluggish kinetics stemming from the unfavorable surface electron properties. Herein, we demonstrate that the confinement of atomically thin Os nanoclusters onto 2D δ-MoN can favorably optimize the surface electron configurations, thereby boosting the material's catalytic performance. MoN-5% Os catalyst with optimal Os loading exhibits high catalytic performance, surpassing that of commercial Pt/C. The enhanced hydrogen evolution performance is attributed to (1) the unique 2D atomically thin nanoarchitecture exposing abundant active sites and (2) the strong electronic interaction between Os nanoclusters and δ-MoN nanosheets, which favorably modulates the surface microenvironment. Theoretical investigation reveals that the confined Os nanoclusters function as surface activators, efficiently modulating the electron properties of MoN, thereby accelerating the sluggish water adsorption and dissociation processes and triggering favorable hydrogen adsorption. |
| author2 |
School of Chemistry, Chemical Engineering and Biotechnology |
| author_facet |
School of Chemistry, Chemical Engineering and Biotechnology Do, Viet-Hung Prabhu, P. Li, Yinghao Xie, Wenjie Kidkhunthod, Pinit Wang, Guangzhao Wang, Xin Lee, Jong-Min |
| format |
Article |
| author |
Do, Viet-Hung Prabhu, P. Li, Yinghao Xie, Wenjie Kidkhunthod, Pinit Wang, Guangzhao Wang, Xin Lee, Jong-Min |
| author_sort |
Do, Viet-Hung |
| title |
Surface activation of atomically thin metal nitride by confined nanoclusters to trigger pH-universal hydrogen evolution |
| title_short |
Surface activation of atomically thin metal nitride by confined nanoclusters to trigger pH-universal hydrogen evolution |
| title_full |
Surface activation of atomically thin metal nitride by confined nanoclusters to trigger pH-universal hydrogen evolution |
| title_fullStr |
Surface activation of atomically thin metal nitride by confined nanoclusters to trigger pH-universal hydrogen evolution |
| title_full_unstemmed |
Surface activation of atomically thin metal nitride by confined nanoclusters to trigger pH-universal hydrogen evolution |
| title_sort |
surface activation of atomically thin metal nitride by confined nanoclusters to trigger ph-universal hydrogen evolution |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/171306 |
| _version_ |
1781793762904637440 |