Optimizing the energy product of exchange-coupled soft/hard Zn0.2Fe2.8O4/SrFe12O19magnets

O. T.L. Traistaru; P. Shyam; M. Christensen; S. P. Madsen

doi:10.1063/5.0103242

Optimizing the energy product of exchange-coupled soft/hard Zn_0.2Fe_2.8O₄/SrFe₁₂O₁₉magnets

O. T.L. Traistaru, P. Shyam, M. Christensen, S. P. Madsen^*

^*Corresponding author for this work

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

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Abstract

Permanent magnets based on ferrites are currently studied as possible alternatives, in several application areas, to rare-earth-based magnets to overcome the barriers of high costs, unavailability, and environmental impact. Their attractiveness lies in the large crystalline anisotropy, ensuring resistance to demagnetization, and the possibility of having their modest saturation magnetization enhanced through exchange-coupling with a compatible soft magnetic material of higher saturation magnetization. Using analytical calculations, a micromagnetic finite element model, and comparison with measurements on a produced sample, the conditions that give the highest possible maximum energy product are determined for ferrite-based exchange-coupled Zn0.2Fe2.8O4/SrFe12O19 soft/hard nanocomposite magnets. Two geometries are considered: A spherical core-shell geometry and a composite granular microstructure. Two sets of material parameters are considered for the granular structure, one from the literature and one obtained by fitting to the measured magnetization data. The results show that it is important to have a well-aligned easy axis of hard grains and that the optimal amount of the soft material depends on the alignment of the hard grains as well as their size, with smaller grains yielding larger (BH)max values. The core-shell model shows that the maximum (BH)max can be strongly enhanced, from ∼40 to ∼60 kJ/m3, by using a hard core diameter of <30 nm and a soft shell thickness of <7 nm. The composite granular structure yields a maximum (BH)max of ∼50 kJ/m3 for a soft volume fraction of 43%.

Original language	English
Article number	163904
Journal	Journal of Applied Physics
Volume	132
Issue	16
Number of pages	11
ISSN	0021-8979
DOIs	https://doi.org/10.1063/5.0103242
Publication status	Published - Oct 2022

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@article{1eaa0c713f48444585ad35bb115356bf,

title = "Optimizing the energy product of exchange-coupled soft/hard Zn0.2Fe2.8O4/SrFe12O19magnets",

abstract = "Permanent magnets based on ferrites are currently studied as possible alternatives, in several application areas, to rare-earth-based magnets to overcome the barriers of high costs, unavailability, and environmental impact. Their attractiveness lies in the large crystalline anisotropy, ensuring resistance to demagnetization, and the possibility of having their modest saturation magnetization enhanced through exchange-coupling with a compatible soft magnetic material of higher saturation magnetization. Using analytical calculations, a micromagnetic finite element model, and comparison with measurements on a produced sample, the conditions that give the highest possible maximum energy product are determined for ferrite-based exchange-coupled Zn0.2Fe2.8O4/SrFe12O19 soft/hard nanocomposite magnets. Two geometries are considered: A spherical core-shell geometry and a composite granular microstructure. Two sets of material parameters are considered for the granular structure, one from the literature and one obtained by fitting to the measured magnetization data. The results show that it is important to have a well-aligned easy axis of hard grains and that the optimal amount of the soft material depends on the alignment of the hard grains as well as their size, with smaller grains yielding larger (BH)max values. The core-shell model shows that the maximum (BH)max can be strongly enhanced, from ∼40 to ∼60 kJ/m3, by using a hard core diameter of <30 nm and a soft shell thickness of <7 nm. The composite granular structure yields a maximum (BH)max of ∼50 kJ/m3 for a soft volume fraction of 43%.",

author = "Traistaru, {O. T.L.} and P. Shyam and M. Christensen and Madsen, {S. P.}",

note = "Funding Information: This study was supported financially by the Innovation Fund Denmark (Project “MAGFLY-Novel Magnets for Flywheel Energy Storage,” No. 7046-00015B), and the Department of Mechanical and Production Engineering at Aarhus University, Denmark. We would like to thank S{\o}ren Dahl and Jakob Weiland H{\o}j from Topsoe A/S for providing the SrFe12O19 sample. Aref Hasen Mamakhel is acknowledged for help with acquiring electron microscopy images and data. Affiliation with Center for Integrated Materials Research (iMAT) at Aarhus University is gratefully acknowledged. Publisher Copyright: {\textcopyright} 2022 Author(s).",

year = "2022",

month = oct,

doi = "10.1063/5.0103242",

language = "English",

volume = "132",

journal = "Journal of Applied Physics",

issn = "0021-8979",

publisher = "American Institute of Physics",

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AU - Traistaru, O. T.L.

AU - Shyam, P.

AU - Christensen, M.

AU - Madsen, S. P.

N1 - Funding Information: This study was supported financially by the Innovation Fund Denmark (Project “MAGFLY-Novel Magnets for Flywheel Energy Storage,” No. 7046-00015B), and the Department of Mechanical and Production Engineering at Aarhus University, Denmark. We would like to thank Søren Dahl and Jakob Weiland Høj from Topsoe A/S for providing the SrFe12O19 sample. Aref Hasen Mamakhel is acknowledged for help with acquiring electron microscopy images and data. Affiliation with Center for Integrated Materials Research (iMAT) at Aarhus University is gratefully acknowledged. Publisher Copyright: © 2022 Author(s).

PY - 2022/10

Y1 - 2022/10

N2 - Permanent magnets based on ferrites are currently studied as possible alternatives, in several application areas, to rare-earth-based magnets to overcome the barriers of high costs, unavailability, and environmental impact. Their attractiveness lies in the large crystalline anisotropy, ensuring resistance to demagnetization, and the possibility of having their modest saturation magnetization enhanced through exchange-coupling with a compatible soft magnetic material of higher saturation magnetization. Using analytical calculations, a micromagnetic finite element model, and comparison with measurements on a produced sample, the conditions that give the highest possible maximum energy product are determined for ferrite-based exchange-coupled Zn0.2Fe2.8O4/SrFe12O19 soft/hard nanocomposite magnets. Two geometries are considered: A spherical core-shell geometry and a composite granular microstructure. Two sets of material parameters are considered for the granular structure, one from the literature and one obtained by fitting to the measured magnetization data. The results show that it is important to have a well-aligned easy axis of hard grains and that the optimal amount of the soft material depends on the alignment of the hard grains as well as their size, with smaller grains yielding larger (BH)max values. The core-shell model shows that the maximum (BH)max can be strongly enhanced, from ∼40 to ∼60 kJ/m3, by using a hard core diameter of <30 nm and a soft shell thickness of <7 nm. The composite granular structure yields a maximum (BH)max of ∼50 kJ/m3 for a soft volume fraction of 43%.

AB - Permanent magnets based on ferrites are currently studied as possible alternatives, in several application areas, to rare-earth-based magnets to overcome the barriers of high costs, unavailability, and environmental impact. Their attractiveness lies in the large crystalline anisotropy, ensuring resistance to demagnetization, and the possibility of having their modest saturation magnetization enhanced through exchange-coupling with a compatible soft magnetic material of higher saturation magnetization. Using analytical calculations, a micromagnetic finite element model, and comparison with measurements on a produced sample, the conditions that give the highest possible maximum energy product are determined for ferrite-based exchange-coupled Zn0.2Fe2.8O4/SrFe12O19 soft/hard nanocomposite magnets. Two geometries are considered: A spherical core-shell geometry and a composite granular microstructure. Two sets of material parameters are considered for the granular structure, one from the literature and one obtained by fitting to the measured magnetization data. The results show that it is important to have a well-aligned easy axis of hard grains and that the optimal amount of the soft material depends on the alignment of the hard grains as well as their size, with smaller grains yielding larger (BH)max values. The core-shell model shows that the maximum (BH)max can be strongly enhanced, from ∼40 to ∼60 kJ/m3, by using a hard core diameter of <30 nm and a soft shell thickness of <7 nm. The composite granular structure yields a maximum (BH)max of ∼50 kJ/m3 for a soft volume fraction of 43%.

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DO - 10.1063/5.0103242

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SN - 0021-8979

VL - 132

JO - Journal of Applied Physics

JF - Journal of Applied Physics

IS - 16

M1 - 163904

ER -

Optimizing the energy product of exchange-coupled soft/hard Zn_0.2Fe_2.8O₄/SrFe₁₂O₁₉magnets

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