Lithiation-induced amorphization of Pd3P2S8 for highly efficient hydrogen evolution

Lithiation-induced amorphization of Pd3P2S8 for highly efficient hydrogen evolution

Engineering material structures at the atomic level is a promising way to tune the physicochemical properties of materials and optimize their performance in various potential applications. Here, we show that the lithiation-induced amorphization of layered crystalline Pd3P2S8 activates this otherwise...

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Main Authors: Zhang, Xiao, Luo, Zhimin, Yu, Peng, Cai, Yongqing, Du, Yonghua, Wu, Daoxiong, Gao, Si, Tan, Chaoliang, Li, Zhong, Ren, Minqin, Osipowicz, Thomas, Chen, Shuangming, Jiang, Zheng, Li, Jiong, Huang, Ying, Yang, Jian, Chen, Ye, Ang, Chung Yen, Zhao, Yanli, Wang, Peng, Song, Li, Wu, Xiaojun, Liu, Zheng, Borgna, Armando, Zhang, Hua
Other Authors: School of Materials Science & Engineering
Format: Article
Language:English
Published: 2020
Subjects:
Engineering::Materials
Lithiation-induced Amorphization
Hydrogen Evolution
Online Access:https://hdl.handle.net/10356/139174
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1391742020-06-01T10:13:51Z Lithiation-induced amorphization of Pd3P2S8 for highly efficient hydrogen evolution Zhang, Xiao Luo, Zhimin Yu, Peng Cai, Yongqing Du, Yonghua Wu, Daoxiong Gao, Si Tan, Chaoliang Li, Zhong Ren, Minqin Osipowicz, Thomas Chen, Shuangming Jiang, Zheng Li, Jiong Huang, Ying Yang, Jian Chen, Ye Ang, Chung Yen Zhao, Yanli Wang, Peng Song, Li Wu, Xiaojun Liu, Zheng Borgna, Armando Zhang, Hua School of Materials Science & Engineering School of Mechanical and Aerospace Engineering School of Physical and Mathematical Sciences Center for Programmable Materials Engineering::Materials Lithiation-induced Amorphization Hydrogen Evolution Engineering material structures at the atomic level is a promising way to tune the physicochemical properties of materials and optimize their performance in various potential applications. Here, we show that the lithiation-induced amorphization of layered crystalline Pd3P2S8 activates this otherwise electrochemically inert material as a highly efficient hydrogen evolution catalyst. Electrochemical lithiation of the layered Pd3P2S8 crystal results in the formation of amorphous lithium-incorporated palladium phosphosulfide nanodots with abundant vacancies. The structure change during the lithiation-induced amorphization process is investigated in detail. The amorphous lithium-incorporated palladium phosphosulfide nanodots exhibit excellent electrocatalytic activity towards the hydrogen evolution reaction with an onset potential of −52 mV, a Tafel slope of 29 mV dec−1 and outstanding long-term stability. Experimental and theoretical investigations reveal that the tuning of morphology and structure of Pd3P2S8 (for example, dimension decrease, crystallinity loss, vacancy formation and lithium incorporation) contribute to the activation of its intrinsically inert electrocatalytic property. This work provides a unique way for structure tuning of a material to effectively manipulate its catalytic properties and functionalities. MOE (Min. of Education, S’pore) 2020-05-18T01:10:15Z 2020-05-18T01:10:15Z 2018 Journal Article Zhang, X., Luo, Z., Yu, P., Cai, Y., Du, Y., Wu, D., . . . Zhang, H. (2018). Lithiation-induced amorphization of Pd3P2S8 for highly efficient hydrogen evolution. Nature Catalysis, 1(6), 460-468. doi:10.1038/s41929-018-0072-y 2520-1158 https://hdl.handle.net/10356/139174 10.1038/s41929-018-0072-y 2-s2.0-85048681307 6 1 460 468 en Nature Catalysis © 2018 Macmillan Publishers Limited, part of Springer Nature. All rights reserved.
institution Nanyang Technological University
building NTU Library
country Singapore
collection DR-NTU
language English
topic Engineering::Materials
Lithiation-induced Amorphization
Hydrogen Evolution
spellingShingle Engineering::Materials
Lithiation-induced Amorphization
Hydrogen Evolution
Zhang, Xiao
Luo, Zhimin
Yu, Peng
Cai, Yongqing
Du, Yonghua
Wu, Daoxiong
Gao, Si
Tan, Chaoliang
Li, Zhong
Ren, Minqin
Osipowicz, Thomas
Chen, Shuangming
Jiang, Zheng
Li, Jiong
Huang, Ying
Yang, Jian
Chen, Ye
Ang, Chung Yen
Zhao, Yanli
Wang, Peng
Song, Li
Wu, Xiaojun
Liu, Zheng
Borgna, Armando
Zhang, Hua
Lithiation-induced amorphization of Pd3P2S8 for highly efficient hydrogen evolution
description Engineering material structures at the atomic level is a promising way to tune the physicochemical properties of materials and optimize their performance in various potential applications. Here, we show that the lithiation-induced amorphization of layered crystalline Pd3P2S8 activates this otherwise electrochemically inert material as a highly efficient hydrogen evolution catalyst. Electrochemical lithiation of the layered Pd3P2S8 crystal results in the formation of amorphous lithium-incorporated palladium phosphosulfide nanodots with abundant vacancies. The structure change during the lithiation-induced amorphization process is investigated in detail. The amorphous lithium-incorporated palladium phosphosulfide nanodots exhibit excellent electrocatalytic activity towards the hydrogen evolution reaction with an onset potential of −52 mV, a Tafel slope of 29 mV dec−1 and outstanding long-term stability. Experimental and theoretical investigations reveal that the tuning of morphology and structure of Pd3P2S8 (for example, dimension decrease, crystallinity loss, vacancy formation and lithium incorporation) contribute to the activation of its intrinsically inert electrocatalytic property. This work provides a unique way for structure tuning of a material to effectively manipulate its catalytic properties and functionalities.
author2 School of Materials Science & Engineering
author_facet School of Materials Science & Engineering
Zhang, Xiao
Luo, Zhimin
Yu, Peng
Cai, Yongqing
Du, Yonghua
Wu, Daoxiong
Gao, Si
Tan, Chaoliang
Li, Zhong
Ren, Minqin
Osipowicz, Thomas
Chen, Shuangming
Jiang, Zheng
Li, Jiong
Huang, Ying
Yang, Jian
Chen, Ye
Ang, Chung Yen
Zhao, Yanli
Wang, Peng
Song, Li
Wu, Xiaojun
Liu, Zheng
Borgna, Armando
Zhang, Hua
format Article
author Zhang, Xiao
Luo, Zhimin
Yu, Peng
Cai, Yongqing
Du, Yonghua
Wu, Daoxiong
Gao, Si
Tan, Chaoliang
Li, Zhong
Ren, Minqin
Osipowicz, Thomas
Chen, Shuangming
Jiang, Zheng
Li, Jiong
Huang, Ying
Yang, Jian
Chen, Ye
Ang, Chung Yen
Zhao, Yanli
Wang, Peng
Song, Li
Wu, Xiaojun
Liu, Zheng
Borgna, Armando
Zhang, Hua
author_sort Zhang, Xiao
title Lithiation-induced amorphization of Pd3P2S8 for highly efficient hydrogen evolution
title_short Lithiation-induced amorphization of Pd3P2S8 for highly efficient hydrogen evolution
title_full Lithiation-induced amorphization of Pd3P2S8 for highly efficient hydrogen evolution
title_fullStr Lithiation-induced amorphization of Pd3P2S8 for highly efficient hydrogen evolution
title_full_unstemmed Lithiation-induced amorphization of Pd3P2S8 for highly efficient hydrogen evolution
title_sort lithiation-induced amorphization of pd3p2s8 for highly efficient hydrogen evolution
publishDate 2020
url https://hdl.handle.net/10356/139174
_version_ 1681057519910256640

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