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231226s2023 xx |||||o 00| ||eng c |
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|a 10.1002/adma.202206576
|2 doi
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|a pubmed25n1156.xml
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|a eng
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|a Wang, Xin
|e verfasserin
|4 aut
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|a Vacancy Defects in 2D Transition Metal Dichalcogenide Electrocatalysts
|b From Aggregated to Atomic Configuration
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|c 2023
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|a Text
|b txt
|2 rdacontent
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|a ƒaComputermedien
|b c
|2 rdamedia
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|a ƒa Online-Ressource
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|2 rdacarrier
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|a Date Revised 14.12.2023
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|a published: Print-Electronic
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|a Citation Status PubMed-not-MEDLINE
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|a © 2023 Wiley-VCH GmbH.
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|a Vacancy defect engineering has been well leveraged to flexibly shape comprehensive physicochemical properties of diverse catalysts. In particular, growing research effort has been devoted to engineering chalcogen anionic vacancies (S/Se/Te) of 2D transition metal dichalcogenides (2D TMDs) toward the ultimate performance limit of electrocatalytic hydrogen evolution reaction (HER). In spite of remarkable progress achieved in the past decade, systematic and in-depth insights into the state-of-the-art vacancy engineering for 2D-TMDs-based electrocatalysis are still lacking. Herein, this review delivers a full picture of vacancy engineering evolving from aggregated to atomic configurations covering their development background, controllable manufacturing, thorough characterization, and representative HER application. Of particular interest, the deep-seated correlations between specific vacancy regulation routes and resulting catalytic performance improvement are logically clarified in terms of atomic rearrangement, charge redistribution, energy band variation, intermediate adsorption-desorption optimization, and charge/mass transfer facilitation. Beyond that, a broader vision is cast into the cutting-edge research fields of vacancy-engineering-based single-atom catalysis and dynamic structure-performance correlations across catalyst service lifetime. Together with critical discussion on residual challenges and future prospects, this review sheds new light on the rational design of advanced defect catalysts and navigates their broader application in high-efficiency energy conversion and storage fields
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|a Journal Article
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|a Review
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|a 2D transition metal dichalcogenides
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|a catalyst reconstruction
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| 650 |
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|a electrocatalysts
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| 650 |
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|a hydrogen evolution reaction
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| 650 |
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|a vacancy defects
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| 650 |
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|a water splitting
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| 700 |
1 |
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|a Wu, Jing
|e verfasserin
|4 aut
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| 700 |
1 |
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|a Zhang, Yuwei
|e verfasserin
|4 aut
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| 700 |
1 |
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|a Sun, Yu
|e verfasserin
|4 aut
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| 700 |
1 |
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|a Ma, Kaikai
|e verfasserin
|4 aut
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| 700 |
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|a Xie, Yong
|e verfasserin
|4 aut
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| 700 |
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|a Zheng, Wenhao
|e verfasserin
|4 aut
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| 700 |
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|a Tian, Zhen
|e verfasserin
|4 aut
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| 700 |
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|a Kang, Zhuo
|e verfasserin
|4 aut
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| 700 |
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|a Zhang, Yue
|e verfasserin
|4 aut
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| 773 |
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|i Enthalten in
|t Advanced materials (Deerfield Beach, Fla.)
|d 1998
|g 35(2023), 50 vom: 25. Dez., Seite e2206576
|w (DE-627)NLM098206397
|x 1521-4095
|7 nnas
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|g volume:35
|g year:2023
|g number:50
|g day:25
|g month:12
|g pages:e2206576
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|u http://dx.doi.org/10.1002/adma.202206576
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