Magnetoelectric Coupling for Metal–Air Batteries

Hengwei Wang; Keliang Wang; Yayu Zuo; Manhui Wei; Pucheng Pei; Pengfei Zhang; Zhuo Chen; Nuo Shang

doi:10.1002/adfm.202210127

Magnetoelectric Coupling for Metal–Air Batteries

Hengwei Wang, Keliang Wang^*, Yayu Zuo, Manhui Wei, Pucheng Pei, Pengfei Zhang, Zhuo Chen, Nuo Shang

^*Corresponding author for this work

School of Mechanical Engineering

Research output: Contribution to journal › Review article › peer-review

24 Citations (Scopus)

Abstract

Metal–air batteries have become one of the new potential sources of electrochemical energy due to the excellent electrochemical characteristics, environmental friendliness and cheap cost. Whereas, the commercialization of the metal–air batteries is still subject to the sluggish kinetics on air electrode and hydrogen evolution corrosion as well as dendrite growth of metal anode. Recently, the applied magnetic field, as a technology for transferring energy across physical space, receives more attention, can improve the performance of metal–air batteries by promoting mass transfer, accelerating charge transfer and enhancing electrocatalytic ability based on magnetohydrodynamic effect, Kelvin force effect, Hall effect, Spin selectivity effect, Maxwell stress effect and Magnetothermal effect. This review provides the recent progress in the research on the relative mechanism and characteristic of the magnetic field in the metal–air batteries.

Original language	English
Article number	2210127
Journal	Advanced Functional Materials
Volume	33
Issue number	5
DOIs	https://doi.org/10.1002/adfm.202210127
Publication status	Published - 26 Jan 2023

Keywords

charge transfer
electrocatalysts
magnetic field
mass transfer
metal–air batteries

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10.1002/adfm.202210127

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title = "Magnetoelectric Coupling for Metal–Air Batteries",

abstract = "Metal–air batteries have become one of the new potential sources of electrochemical energy due to the excellent electrochemical characteristics, environmental friendliness and cheap cost. Whereas, the commercialization of the metal–air batteries is still subject to the sluggish kinetics on air electrode and hydrogen evolution corrosion as well as dendrite growth of metal anode. Recently, the applied magnetic field, as a technology for transferring energy across physical space, receives more attention, can improve the performance of metal–air batteries by promoting mass transfer, accelerating charge transfer and enhancing electrocatalytic ability based on magnetohydrodynamic effect, Kelvin force effect, Hall effect, Spin selectivity effect, Maxwell stress effect and Magnetothermal effect. This review provides the recent progress in the research on the relative mechanism and characteristic of the magnetic field in the metal–air batteries.",

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AU - Wang, Hengwei

AU - Wang, Keliang

AU - Zuo, Yayu

AU - Wei, Manhui

AU - Pei, Pucheng

AU - Zhang, Pengfei

AU - Chen, Zhuo

AU - Shang, Nuo

PY - 2023/1/26

Y1 - 2023/1/26

N2 - Metal–air batteries have become one of the new potential sources of electrochemical energy due to the excellent electrochemical characteristics, environmental friendliness and cheap cost. Whereas, the commercialization of the metal–air batteries is still subject to the sluggish kinetics on air electrode and hydrogen evolution corrosion as well as dendrite growth of metal anode. Recently, the applied magnetic field, as a technology for transferring energy across physical space, receives more attention, can improve the performance of metal–air batteries by promoting mass transfer, accelerating charge transfer and enhancing electrocatalytic ability based on magnetohydrodynamic effect, Kelvin force effect, Hall effect, Spin selectivity effect, Maxwell stress effect and Magnetothermal effect. This review provides the recent progress in the research on the relative mechanism and characteristic of the magnetic field in the metal–air batteries.

AB - Metal–air batteries have become one of the new potential sources of electrochemical energy due to the excellent electrochemical characteristics, environmental friendliness and cheap cost. Whereas, the commercialization of the metal–air batteries is still subject to the sluggish kinetics on air electrode and hydrogen evolution corrosion as well as dendrite growth of metal anode. Recently, the applied magnetic field, as a technology for transferring energy across physical space, receives more attention, can improve the performance of metal–air batteries by promoting mass transfer, accelerating charge transfer and enhancing electrocatalytic ability based on magnetohydrodynamic effect, Kelvin force effect, Hall effect, Spin selectivity effect, Maxwell stress effect and Magnetothermal effect. This review provides the recent progress in the research on the relative mechanism and characteristic of the magnetic field in the metal–air batteries.

KW - charge transfer

KW - electrocatalysts

KW - magnetic field

KW - mass transfer

KW - metal–air batteries

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DO - 10.1002/adfm.202210127

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JO - Advanced Functional Materials

JF - Advanced Functional Materials

IS - 5

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ER -

Magnetoelectric Coupling for Metal–Air Batteries

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Keywords

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