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Designing Advanced Vanadium-Based Materials to Achieve Electrochemically Active Multielectron Reactions in Sodium/Potassium-Ion Batteries
Mingzhe Chen1; Qiannan Liu2; Zhe Hu2; Yanyan Zhang1; Guichuan Xing1; Yuxin Tang1; Shu-Lei Chou2
2020-11-10
Source PublicationAdvanced Energy Materials
ISSN1614-6832
Volume10Issue:42Pages:2002244
Other Abstract

Next-generation sodium-ion batteries (SIBs) and potassium-ion batteries (PIBs) are considered to be promising alternatives to replace current lithium-ion batteries due to the high abundance of sodium and potassium resources. New energetic vanadium-based compounds that undergoes multielectron reactions and demonstrate good sodium/potassium storage capability, provide new solutions for high-performance SIBs/PIBs in terms of high energy/power density and long-time cyclability. So far, desirable rich redox centers (V-V), consolidated frameworks, and the high theoretical capacities of vanadium-based compounds have been widely explored for practical applications. Rational materials design utilizing vanadium multiredox centers and the fundamental understanding of their charge-transfer processes and mechanisms are critical in the development of high-performance battery systems. The scientific importance and basic design strategies for high performance V-based anode/cathode materials, structure-function properties and state-of-the-art understanding of V-based electrode materials are herein classified and highlighted alongside their design strategies. The important role of the valence electron layer of vanadium, and the scientific advances of vanadium partitions in other electrochemical behaviors are also summarized in detail. Finally, relevant strategies and perspectives discussed in this review provide practical guidance to explore the undiscovered potentials of multi-electron reaction relationships of not only V-based composites, but also other types of electrode materials.

DOI10.1002/aenm.202002244
URLView the original
Indexed BySCIE
Language英語English
WOS Research AreaChemistry ; Energy & Fuels ; Materials Science ; Physics
WOS SubjectChemistry, Physical ; Energy & Fuels ; Materials Science, Multidisciplinary ; Physics, Applied ; Physics, Condensed Matter
WOS IDWOS:000574859800001
PublisherWILEY-V C H VERLAG GMBH, POSTFACH 101161, 69451 WEINHEIM, GERMANY
Scopus ID2-s2.0-85092057641
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Cited Times [WOS]:43   [WOS Record]     [Related Records in WOS]
Document TypeJournal article
CollectionINSTITUTE OF APPLIED PHYSICS AND MATERIALS ENGINEERING
Corresponding AuthorYuxin Tang; Shu-Lei Chou
Affiliation1.Institute of Applied Physics and Materials Engineering,University of Macau,Macao
2.Institute for Superconducting and Electronic Materials,Australian Institute for Innovative Materials,University of Wollongong,North Wollongong,Innovation Campus, Squires Way,2522,Australia
First Author AffilicationINSTITUTE OF APPLIED PHYSICS AND MATERIALS ENGINEERING
Corresponding Author AffilicationINSTITUTE OF APPLIED PHYSICS AND MATERIALS ENGINEERING
Recommended Citation
GB/T 7714
Mingzhe Chen,Qiannan Liu,Zhe Hu,et al. Designing Advanced Vanadium-Based Materials to Achieve Electrochemically Active Multielectron Reactions in Sodium/Potassium-Ion Batteries[J]. Advanced Energy Materials,2020,10(42):2002244.
APA Mingzhe Chen,Qiannan Liu,Zhe Hu,Yanyan Zhang,Guichuan Xing,Yuxin Tang,&Shu-Lei Chou.(2020).Designing Advanced Vanadium-Based Materials to Achieve Electrochemically Active Multielectron Reactions in Sodium/Potassium-Ion Batteries.Advanced Energy Materials,10(42),2002244.
MLA Mingzhe Chen,et al."Designing Advanced Vanadium-Based Materials to Achieve Electrochemically Active Multielectron Reactions in Sodium/Potassium-Ion Batteries".Advanced Energy Materials 10.42(2020):2002244.
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