Review of regulating Zn<sup>2+</sup> solvation structures in aqueous zinc-ion batteries

Zhang, W.; Chen, Yu‐Fang; Gao, Hongjing; Xie, Wei; Gao, Peng; Zheng, Chunman; Xiao, Peitao

doi:10.1088/2752-5724/ace3de

Cited by 11 publications

(1 citation statement)

References 127 publications

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“…Furthermore, incorporating various theoretical calculations such as density functional theory calculations, finite element modeling, molecular dynamics simulations, and Arrhenius equations based on charge transfer resistance is imperative. 119 Enhanced and innovative characterization methods facilitate a deeper comprehension of battery dynamics, enabling a more accurate assessment of the merits and drawbacks of modified materials and solutions in achieving superior performance of AZIBs. For instance, Zhou et al 120 introduced a real-time comprehensive characterization system called the “3M” system.…”

Section: Conclusion and Prospectsmentioning

confidence: 99%

Tailoring desolvation strategies for aqueous zinc-ion batteries

Ma,

Wang,

et al. 2024

Energy Environ. Sci.

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Section: Conclusion and Prospectsmentioning

confidence: 99%

Tailoring desolvation strategies for aqueous zinc-ion batteries

Ma,

Wang,

et al. 2024

Energy Environ. Sci.

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Co‐Substitution Engineering Boosting the Kinetics and Stablity of VO₂ for Zn Ion Batteries

Wang,

Cui,

Wang

et al. 2024

Adv Funct Materials

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VO2 is considered as one of the most likely cathode materials to be commercialized for large‐scale application in AZIBs and is at the forefront of aqueous batteries, but its lower electrical conductivity, slower Zn2+ mobility, as well as voltage degradation and structural collapse due to vanadium solubilization have limited its further development. Herein, a Co‐substitution engineering strategy is proposed, which is introducing heteroatom Co2+ doping substitution and oxygen vacancy substitution to stabilize structure and promote ionic/electronic conductivity, leading an enhanced Zn ion storage behavior. The Co‐substituted VO2 (Co0.03V0.97O2‐x, denote as Ov‐CoVO) is reported in this paper, Co‐substitution inhibits vanadium dissolution of VO2 in AZIBs, even in the acetionitrile system. DFT calculations show that Ov‐CoVO has a more stable structure as well as a faster electronic/ionic conductivity. Consequently, the Ov‐CoVO||ZnOTF||Zn battery (aqueous) can deliver a remarkable capacity of 475 mAh g−1 at 0.2 A g−1 with 99.1% capacity retention after 200 cycles, still maintains excellent cycling stability in Ov‐CoVO||ZnTFSI||Zn (acetionitrile electrolyte) at 0.1 A g−1. In addition, compared to VO2, the charge transfer resistance and Zn2+ iffusion coefficient of Ov‐CoVO are significantly enhanced. This work broadens the scope for research cathode materials for high performance ZIBs.

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Designer Anions for Better Rechargeable Lithium Batteries and Beyond

Song,

Wang,

Feng

et al. 2024

Advanced Materials

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Non‐aqueous electrolytes, generally consisting of metal salts and solvating media, are indispensable elements for building rechargeable batteries. As the major sources of ionic charges, the intrinsic characters of salt anions are of particular importance in determining the fundamental properties of bulk electrolyte, as well as the features of the resulting electrode‐electrolyte interphases/interfaces. To cope with the increasing demand for better rechargeable batteries requested by emerging application domains, the structural design and modifications of salt anions are highly desired. Here, salt anions for lithium and other monovalent (e.g., sodium and potassium) and multivalent (e.g., magnesium, calcium, zinc, and aluminum) rechargeable batteries are outlined. Fundamental considerations on the design of salt anions are provided, particularly involving specific requirements imposed by different cell chemistries. Historical evolution and possible synthetic methodologies for metal salts with representative salt anions are reviewed. Recent advances in tailoring the anionic structures for rechargeable batteries are scrutinized, and due attention is paid to the paradigm shift from liquid to solid electrolytes, from intercalation to conversion/alloying‐type electrodes, from lithium to other kinds of rechargeable batteries. The remaining challenges and key research directions in the development of robust salt anions are also discussed.This article is protected by copyright. All rights reserved

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Review of regulating Zn²⁺ solvation structures in aqueous zinc-ion batteries

Cited by 11 publications

References 127 publications

Tailoring desolvation strategies for aqueous zinc-ion batteries

Tailoring desolvation strategies for aqueous zinc-ion batteries

Co‐Substitution Engineering Boosting the Kinetics and Stablity of VO₂ for Zn Ion Batteries

Designer Anions for Better Rechargeable Lithium Batteries and Beyond

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Review of regulating Zn2+ solvation structures in aqueous zinc-ion batteries

Cited by 11 publications

References 127 publications

Tailoring desolvation strategies for aqueous zinc-ion batteries

Tailoring desolvation strategies for aqueous zinc-ion batteries

Co‐Substitution Engineering Boosting the Kinetics and Stablity of VO2 for Zn Ion Batteries

Designer Anions for Better Rechargeable Lithium Batteries and Beyond

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Product

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Review of regulating Zn²⁺ solvation structures in aqueous zinc-ion batteries

Co‐Substitution Engineering Boosting the Kinetics and Stablity of VO₂ for Zn Ion Batteries