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Abstract
A nanocomposite consisting of iron disilicide nanocrystals embedded in a Si matrix was prepared from industry-grade ferrosilicon by ball milling and subsequent heat treatment. By tailoring the heat treatment temperature either the metallic α-FeSi2 or the semiconducting β-FeSi2 phase could be made the dominant one, as indicated by x-ray diffraction. Magnetization curve and zero-field cooled/field cooled measurements revealed that ferromagnetic and superparamagnetic centers are present in the nanocomposites, which could be attributed to Fe-rich defective regions at the surface of the iron disilicide nanocrystals. For both nanocomposites, containing either mainly the α or β phase, we could show that the magnetization can be varied by about 40% by electrochemical lithiation and delithiation of the surrounding Si matrix, with up to 6.5% of the magnetization change being reversible. These variations could be attributed to the formation of additional Fe-rich magnetic regions, induced by a local change of the Fe/Si fraction at the FeSi2/Si interfaces, and their subsequent partial elimination. Thus, this work demonstrates a new concept for how an 'indirect magneto-ionic effect' can be obtained in composite materials consisting of a phase prone to the electrochemical ion uptake (i.e. the Si matrix) and a magnetic phase (i.e. the FeSi2 nanocrystals).
Original language | English |
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Article number | 03LT03 |
Journal | JPhys Materials |
Volume | 7 |
Issue number | 3 |
DOIs | |
Publication status | Published - 17 Jul 2024 |
Keywords
- Fe-Si alloy
- lithium-ion battery
- magneto-ionics
- nanomagnetism
- voltage control of magnetism
ASJC Scopus subject areas
- Condensed Matter Physics
- Atomic and Molecular Physics, and Optics
- General Materials Science
Fields of Expertise
- Advanced Materials Science
Cooperations
- NAWI Graz
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Dive into the research topics of 'Indirect magneto-ionic effect in FeSi2/Si nanocomposite induced by electrochemical lithiation and delithiation'. Together they form a unique fingerprint.Projects
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Energy-related Materials & Nanoporous Metals
Brossmann, U., Steyskal, E. & Würschum, R.
1/01/00 → 31/12/24
Project: Research area