Cobalt-Modulated Molybdenum-Dinitrogen Interaction in MoS2 for Catalyzing Ammonia Synthesis

Jing Zhang; Xiaoyin Tian; Mingjie Liu; Hua Guo; Jiadong Zhou; Qiyi Fang; Zheng Liu; Qin Wu; Jun Lou

doi:10.1021/jacs.9b02501

Cobalt-Modulated Molybdenum-Dinitrogen Interaction in MoS₂ for Catalyzing Ammonia Synthesis

Jing Zhang, Xiaoyin Tian, Mingjie Liu, Hua Guo, Jiadong Zhou, Qiyi Fang, Zheng Liu, Qin Wu, Jun Lou^*

^*Corresponding author for this work

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

212 Citations (Scopus)

Abstract

Dinitrogen conversion to ammonia via electrochemical reduction with over 10% Faradaic efficiency is demonstrated in this work. Co-doped MoS_2-x polycrystalline nanosheets with S vacancies as the catalysts are loaded onto carbon cloth by hydrothermal growth from Mo, Co, and S precursors. A sulfur vacancy on the MoS_2-x basal plane mimicking the natural Mo-nitrogenase active site is modified by Co doping and exhibits superior dinitrogen-to-ammonia conversion activity. Density-functional simulation reveals that the free energy barrier, which can be compensated by applied overpotential, is reduced from 1.62 to 0.59 eV after Co doping. Meanwhile, dinitrogen tends to be chemically adsorbed to defective MoS_2-x, which effectively activates the dinitrogen molecule for the dissociation of the NN triple bond. This process is further accelerated by Co doping, resulting from the modulation of Mo-N bonding configuration.

Original language	English
Pages (from-to)	19269-19275
Number of pages	7
Journal	Journal of the American Chemical Society
Volume	141
Issue number	49
DOIs	https://doi.org/10.1021/jacs.9b02501
Publication status	Published - Dec 11 2019
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2019 American Chemical Society.

ASJC Scopus Subject Areas

Catalysis
General Chemistry
Biochemistry
Colloid and Surface Chemistry

Access to Document

10.1021/jacs.9b02501

Cite this

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title = "Cobalt-Modulated Molybdenum-Dinitrogen Interaction in MoS2 for Catalyzing Ammonia Synthesis",

abstract = "Dinitrogen conversion to ammonia via electrochemical reduction with over 10% Faradaic efficiency is demonstrated in this work. Co-doped MoS2-x polycrystalline nanosheets with S vacancies as the catalysts are loaded onto carbon cloth by hydrothermal growth from Mo, Co, and S precursors. A sulfur vacancy on the MoS2-x basal plane mimicking the natural Mo-nitrogenase active site is modified by Co doping and exhibits superior dinitrogen-to-ammonia conversion activity. Density-functional simulation reveals that the free energy barrier, which can be compensated by applied overpotential, is reduced from 1.62 to 0.59 eV after Co doping. Meanwhile, dinitrogen tends to be chemically adsorbed to defective MoS2-x, which effectively activates the dinitrogen molecule for the dissociation of the NN triple bond. This process is further accelerated by Co doping, resulting from the modulation of Mo-N bonding configuration.",

author = "Jing Zhang and Xiaoyin Tian and Mingjie Liu and Hua Guo and Jiadong Zhou and Qiyi Fang and Zheng Liu and Qin Wu and Jun Lou",

note = "Publisher Copyright: {\textcopyright} 2019 American Chemical Society.",

year = "2019",

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T1 - Cobalt-Modulated Molybdenum-Dinitrogen Interaction in MoS2 for Catalyzing Ammonia Synthesis

AU - Zhang, Jing

AU - Tian, Xiaoyin

AU - Liu, Mingjie

AU - Guo, Hua

AU - Zhou, Jiadong

AU - Fang, Qiyi

AU - Liu, Zheng

AU - Wu, Qin

AU - Lou, Jun

PY - 2019/12/11

Y1 - 2019/12/11

N2 - Dinitrogen conversion to ammonia via electrochemical reduction with over 10% Faradaic efficiency is demonstrated in this work. Co-doped MoS2-x polycrystalline nanosheets with S vacancies as the catalysts are loaded onto carbon cloth by hydrothermal growth from Mo, Co, and S precursors. A sulfur vacancy on the MoS2-x basal plane mimicking the natural Mo-nitrogenase active site is modified by Co doping and exhibits superior dinitrogen-to-ammonia conversion activity. Density-functional simulation reveals that the free energy barrier, which can be compensated by applied overpotential, is reduced from 1.62 to 0.59 eV after Co doping. Meanwhile, dinitrogen tends to be chemically adsorbed to defective MoS2-x, which effectively activates the dinitrogen molecule for the dissociation of the NN triple bond. This process is further accelerated by Co doping, resulting from the modulation of Mo-N bonding configuration.

AB - Dinitrogen conversion to ammonia via electrochemical reduction with over 10% Faradaic efficiency is demonstrated in this work. Co-doped MoS2-x polycrystalline nanosheets with S vacancies as the catalysts are loaded onto carbon cloth by hydrothermal growth from Mo, Co, and S precursors. A sulfur vacancy on the MoS2-x basal plane mimicking the natural Mo-nitrogenase active site is modified by Co doping and exhibits superior dinitrogen-to-ammonia conversion activity. Density-functional simulation reveals that the free energy barrier, which can be compensated by applied overpotential, is reduced from 1.62 to 0.59 eV after Co doping. Meanwhile, dinitrogen tends to be chemically adsorbed to defective MoS2-x, which effectively activates the dinitrogen molecule for the dissociation of the NN triple bond. This process is further accelerated by Co doping, resulting from the modulation of Mo-N bonding configuration.

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