Lithium-Ion Battery Cycling for Magnetism Control

Magnetization and electric-field coupling is fundamentally interesting and important. Specifically, current- or voltage-driven magnetization switching at room temperature is highly desirable from scientific and technological viewpoints. Herein, we demonstrate that magnetization can be controlled via...

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Published in	Nano letters Vol. 16; no. 1; pp. 583 - 587
Main Authors	Zhang, Qingyun, Luo, Xi, Wang, Luning, Zhang, Lifang, Khalid, Bilal, Gong, Jianghong, Wu, Hui
Format	Journal Article
Language	English
Published	United States American Chemical Society 13.01.2016
Subjects	voltage tuning LIB magnetization control nano Fe2O3
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Abstract	Magnetization and electric-field coupling is fundamentally interesting and important. Specifically, current- or voltage-driven magnetization switching at room temperature is highly desirable from scientific and technological viewpoints. Herein, we demonstrate that magnetization can be controlled via the discharge–charge cycling of a lithium-ion battery (LIB) with rationally designed electrode nanomaterials. Reversible manipulation of magnetism over 3 orders of magnitude was achieved by controlling the lithiation/delithiation of a nanoscale α-Fe2O3-based electrode. The process was completed rapidly under room-temperature conditions. Our results indicate that in addition to energy storage LIBs, which have been under continuous development for several decades, provide exciting opportunities for the multireversible magnetization of magnetic fields.
AbstractList	Magnetization and electric-field coupling is fundamentally interesting and important. Specifically, current- or voltage-driven magnetization switching at room temperature is highly desirable from scientific and technological viewpoints. Herein, we demonstrate that magnetization can be controlled via the discharge–charge cycling of a lithium-ion battery (LIB) with rationally designed electrode nanomaterials. Reversible manipulation of magnetism over 3 orders of magnitude was achieved by controlling the lithiation/delithiation of a nanoscale α-Fe2O3-based electrode. The process was completed rapidly under room-temperature conditions. Our results indicate that in addition to energy storage LIBs, which have been under continuous development for several decades, provide exciting opportunities for the multireversible magnetization of magnetic fields.
Author	Zhang, Qingyun Khalid, Bilal Wang, Luning Luo, Xi Wu, Hui Zhang, Lifang Gong, Jianghong
AuthorAffiliation	Tsinghua University School of Materials Science and Engineering University of Science and Technology Beijing State Key Laboratory of New Ceramics and Fine Processing, School of Materials Science and Engineering
AuthorAffiliation_xml	– name: University of Science and Technology Beijing – name: State Key Laboratory of New Ceramics and Fine Processing, School of Materials Science and Engineering – name: Tsinghua University – name: School of Materials Science and Engineering
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