Current progress and future perspectives of electrolytes for rechargeable aluminum-ion batteries
Current progress and future perspectives of electrolytes for rechargeable aluminum-ion batteries
Aluminum-ion batteries (AIBs) with Al metal anode are attracting increasing research interest on account of their high safety, low cost, large volumetric energy density (≈8046 mA h cm−3), and environmental friendliness. Specifically, the reversible Al electrostripping/deposition is achieved with the rapid development of room temperature ionic liquids, and rapid progress has been made in fabricating high-performance and durable AIBs during the past decade. This review provides an integrated comprehension of the evolution of AIBs and highlights the development of various non-aqueous and aqueous electrolytes including high-temperature molten salts, room temperature ionic liquids, and gel–polymer electrolytes. The critical issues on the interplay of electrolytes are outlined in terms of the voltage window span, the effective ion species during charge storage (Al3+ or (Formula presented.)) and their underlying charge transfer (e.g., interfacial transfer and diffusion), and the solid electrolyte interface formation and its role. Following the critical insight, future perspectives on how to practically design feasible AIBs are given.
aluminum-ion batteries, electrochemical energy storage, electrolytes, ionic liquids, solid electrolyte interface
Ma, Dongwei
8a9dcc14-1023-4d66-8d57-286cebf8823c
Yuan, Du
339dc92b-1e01-4fda-b043-99c5ff178cac
Ponce de León, Carlos
4f265b65-2e8c-4604-8b12-7cdf9f221383
Xia, Xin
686d8c0e-dd42-4006-a317-6ada608a0b46
Pan, Jiahong
cc27069e-89c3-4459-a61d-bc25edb990bc
Ma, Dongwei
8a9dcc14-1023-4d66-8d57-286cebf8823c
Yuan, Du
339dc92b-1e01-4fda-b043-99c5ff178cac
Ponce de León, Carlos
4f265b65-2e8c-4604-8b12-7cdf9f221383
Xia, Xin
686d8c0e-dd42-4006-a317-6ada608a0b46
Pan, Jiahong
cc27069e-89c3-4459-a61d-bc25edb990bc
Ma, Dongwei, Yuan, Du, Ponce de León, Carlos, Xia, Xin and Pan, Jiahong
(2021)
Current progress and future perspectives of electrolytes for rechargeable aluminum-ion batteries.
Energy and Environmental Materials.
(doi:10.1002/eem2.12301).
Abstract
Aluminum-ion batteries (AIBs) with Al metal anode are attracting increasing research interest on account of their high safety, low cost, large volumetric energy density (≈8046 mA h cm−3), and environmental friendliness. Specifically, the reversible Al electrostripping/deposition is achieved with the rapid development of room temperature ionic liquids, and rapid progress has been made in fabricating high-performance and durable AIBs during the past decade. This review provides an integrated comprehension of the evolution of AIBs and highlights the development of various non-aqueous and aqueous electrolytes including high-temperature molten salts, room temperature ionic liquids, and gel–polymer electrolytes. The critical issues on the interplay of electrolytes are outlined in terms of the voltage window span, the effective ion species during charge storage (Al3+ or (Formula presented.)) and their underlying charge transfer (e.g., interfacial transfer and diffusion), and the solid electrolyte interface formation and its role. Following the critical insight, future perspectives on how to practically design feasible AIBs are given.
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e-pub ahead of print date: 30 October 2021
Keywords:
aluminum-ion batteries, electrochemical energy storage, electrolytes, ionic liquids, solid electrolyte interface
Identifiers
Local EPrints ID: 471204
URI: http://eprints.soton.ac.uk/id/eprint/471204
ISSN: 2575-0348
PURE UUID: bc2b13c1-f3ae-481f-adbf-5ca8b29e4eba
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Date deposited: 31 Oct 2022 17:46
Last modified: 17 Mar 2024 13:07
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Contributors
Author:
Dongwei Ma
Author:
Du Yuan
Author:
Carlos Ponce de León
Author:
Xin Xia
Author:
Jiahong Pan
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