Modulating the Nitrate Reduction Pathway on Unconventional Phase Ultrathin Nanoalloys for Selective Ammonia Electrosynthesis

Jingwen Zhou; Fu Liu; Zhihang Xu; Jian An Yin; Liang Guo; Fengkun Hao; Yunhao Wang; Yuecheng Xiong; Xichen Zhou; Cheng Wang; Yangbo Ma; Xiang Meng; Pengyi Lu; Jinwen Yin; An Zhang; Jie Wang; Chenliang Ye; Qiang Li; Chongyi Ling; Hsiao Chien Chen; Hao Ming Chen; Ye Zhu; Jian Lu; Zhanxi Fan

doi:10.1021/jacs.5c07490

Modulating the Nitrate Reduction Pathway on Unconventional Phase Ultrathin Nanoalloys for Selective Ammonia Electrosynthesis

Jingwen Zhou
, Fu Liu
, Zhihang Xu
, Jian An Yin
, Liang Guo
, Fengkun Hao
, Yunhao Wang
, Yuecheng Xiong
, Xichen Zhou
, Cheng Wang
, Yangbo Ma
, Xiang Meng
, Pengyi Lu
, Jinwen Yin
, An Zhang
, Jie Wang
, Chenliang Ye
, Qiang Li
, Chongyi Ling
, Hsiao Chien Chen^*

Hao Ming Chen, Ye Zhu^*, Jian Lu^*, Zhanxi Fan^*

^*Corresponding author for this work

Master Program in Nano-Electronic Engineering and Design

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

19 Scopus citations

Abstract

Ammonia (NH₃) electrosynthesis from nitrate-polluted wastewater is a challenging but meaningful technique for the future green chemical and sewage disposal industries. The dominant difficulties lie in how to realize a highly selective, low-overpotential, and rapid electrocatalytic nitrate reduction reaction (NO₃RR). Herein, we propose a catalyst crystal phase and electrode/electrolyte interface dual engineering strategy to enhance the neutral NO₃RR performance of ultrathin alloy nanostructures. The obtained unconventional 2H-RhCu not only shows higher intrinsic NH₃ selectivity than its traditional face-centered cubic and amorphous/crystalline counterparts but also delivers superior Faradaic efficiency and yield rate toward NH₃ in K⁺-based electrolyte over those in Li⁺/Na⁺-based ones. In situ studies and theoretical calculations reveal that the faster generation/conversion kinetics of key intermediates, weaker N-N recombination, and unique *NO_bri adsorption configuration at electrode/electrolyte interfaces account for this significant enhancement. In addition, rechargeable Zn-nitrate/methanol flow batteries with 2H-RhCu were constructed as a demonstration of potential applications.

Original language	English
Pages (from-to)	23226-23238
Number of pages	13
Journal	Journal of the American Chemical Society
Volume	147
Issue number	26
DOIs	https://doi.org/10.1021/jacs.5c07490
State	Published - 02 07 2025

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Publisher Copyright:
© 2025 The Authors. Published by American Chemical Society.

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10.1021/jacs.5c07490

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Zhou, J., Liu, F., Xu, Z., Yin, J. A., Guo, L., Hao, F., Wang, Y., Xiong, Y., Zhou, X., Wang, C., Ma, Y., Meng, X., Lu, P., Yin, J., Zhang, A., Wang, J., Ye, C., Li, Q., Ling, C., ... Fan, Z. (2025). Modulating the Nitrate Reduction Pathway on Unconventional Phase Ultrathin Nanoalloys for Selective Ammonia Electrosynthesis. Journal of the American Chemical Society, 147(26), 23226-23238. https://doi.org/10.1021/jacs.5c07490

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title = "Modulating the Nitrate Reduction Pathway on Unconventional Phase Ultrathin Nanoalloys for Selective Ammonia Electrosynthesis",

abstract = "Ammonia (NH3) electrosynthesis from nitrate-polluted wastewater is a challenging but meaningful technique for the future green chemical and sewage disposal industries. The dominant difficulties lie in how to realize a highly selective, low-overpotential, and rapid electrocatalytic nitrate reduction reaction (NO3RR). Herein, we propose a catalyst crystal phase and electrode/electrolyte interface dual engineering strategy to enhance the neutral NO3RR performance of ultrathin alloy nanostructures. The obtained unconventional 2H-RhCu not only shows higher intrinsic NH3 selectivity than its traditional face-centered cubic and amorphous/crystalline counterparts but also delivers superior Faradaic efficiency and yield rate toward NH3 in K+-based electrolyte over those in Li+/Na+-based ones. In situ studies and theoretical calculations reveal that the faster generation/conversion kinetics of key intermediates, weaker N-N recombination, and unique *NObri adsorption configuration at electrode/electrolyte interfaces account for this significant enhancement. In addition, rechargeable Zn-nitrate/methanol flow batteries with 2H-RhCu were constructed as a demonstration of potential applications.",

author = "Jingwen Zhou and Fu Liu and Zhihang Xu and Yin, \{Jian An\} and Liang Guo and Fengkun Hao and Yunhao Wang and Yuecheng Xiong and Xichen Zhou and Cheng Wang and Yangbo Ma and Xiang Meng and Pengyi Lu and Jinwen Yin and An Zhang and Jie Wang and Chenliang Ye and Qiang Li and Chongyi Ling and Chen, \{Hsiao Chien\} and Chen, \{Hao Ming\} and Ye Zhu and Jian Lu and Zhanxi Fan",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors. Published by American Chemical Society.",

year = "2025",

month = jul,

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doi = "10.1021/jacs.5c07490",

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Zhou, J, Liu, F, Xu, Z, Yin, JA, Guo, L, Hao, F, Wang, Y, Xiong, Y, Zhou, X, Wang, C, Ma, Y, Meng, X, Lu, P, Yin, J, Zhang, A, Wang, J, Ye, C, Li, Q, Ling, C, Chen, HC, Chen, HM, Zhu, Y, Lu, J & Fan, Z 2025, 'Modulating the Nitrate Reduction Pathway on Unconventional Phase Ultrathin Nanoalloys for Selective Ammonia Electrosynthesis', Journal of the American Chemical Society, vol. 147, no. 26, pp. 23226-23238. https://doi.org/10.1021/jacs.5c07490

TY - JOUR

T1 - Modulating the Nitrate Reduction Pathway on Unconventional Phase Ultrathin Nanoalloys for Selective Ammonia Electrosynthesis

AU - Zhou, Jingwen

AU - Liu, Fu

AU - Xu, Zhihang

AU - Yin, Jian An

AU - Guo, Liang

AU - Hao, Fengkun

AU - Wang, Yunhao

AU - Xiong, Yuecheng

AU - Zhou, Xichen

AU - Wang, Cheng

AU - Ma, Yangbo

AU - Meng, Xiang

AU - Lu, Pengyi

AU - Yin, Jinwen

AU - Zhang, An

AU - Wang, Jie

AU - Ye, Chenliang

AU - Li, Qiang

AU - Ling, Chongyi

AU - Chen, Hsiao Chien

AU - Chen, Hao Ming

AU - Zhu, Ye

AU - Lu, Jian

AU - Fan, Zhanxi

PY - 2025/7/2

Y1 - 2025/7/2

N2 - Ammonia (NH3) electrosynthesis from nitrate-polluted wastewater is a challenging but meaningful technique for the future green chemical and sewage disposal industries. The dominant difficulties lie in how to realize a highly selective, low-overpotential, and rapid electrocatalytic nitrate reduction reaction (NO3RR). Herein, we propose a catalyst crystal phase and electrode/electrolyte interface dual engineering strategy to enhance the neutral NO3RR performance of ultrathin alloy nanostructures. The obtained unconventional 2H-RhCu not only shows higher intrinsic NH3 selectivity than its traditional face-centered cubic and amorphous/crystalline counterparts but also delivers superior Faradaic efficiency and yield rate toward NH3 in K+-based electrolyte over those in Li+/Na+-based ones. In situ studies and theoretical calculations reveal that the faster generation/conversion kinetics of key intermediates, weaker N-N recombination, and unique *NObri adsorption configuration at electrode/electrolyte interfaces account for this significant enhancement. In addition, rechargeable Zn-nitrate/methanol flow batteries with 2H-RhCu were constructed as a demonstration of potential applications.

AB - Ammonia (NH3) electrosynthesis from nitrate-polluted wastewater is a challenging but meaningful technique for the future green chemical and sewage disposal industries. The dominant difficulties lie in how to realize a highly selective, low-overpotential, and rapid electrocatalytic nitrate reduction reaction (NO3RR). Herein, we propose a catalyst crystal phase and electrode/electrolyte interface dual engineering strategy to enhance the neutral NO3RR performance of ultrathin alloy nanostructures. The obtained unconventional 2H-RhCu not only shows higher intrinsic NH3 selectivity than its traditional face-centered cubic and amorphous/crystalline counterparts but also delivers superior Faradaic efficiency and yield rate toward NH3 in K+-based electrolyte over those in Li+/Na+-based ones. In situ studies and theoretical calculations reveal that the faster generation/conversion kinetics of key intermediates, weaker N-N recombination, and unique *NObri adsorption configuration at electrode/electrolyte interfaces account for this significant enhancement. In addition, rechargeable Zn-nitrate/methanol flow batteries with 2H-RhCu were constructed as a demonstration of potential applications.

UR - https://www.scopus.com/pages/publications/105008886407

U2 - 10.1021/jacs.5c07490

DO - 10.1021/jacs.5c07490

M3 - 文章

C2 - 40538059

AN - SCOPUS:105008886407

SN - 0002-7863

VL - 147

SP - 23226

EP - 23238

JO - Journal of the American Chemical Society

JF - Journal of the American Chemical Society

IS - 26

ER -

Modulating the Nitrate Reduction Pathway on Unconventional Phase Ultrathin Nanoalloys for Selective Ammonia Electrosynthesis

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