Synthesis, magnetic properties, and modelling of remagnetization of an artificial antiferromagnet based on  L 1 0 -PdFe

M. V. Pasynkov; Пасынков М. В.; I. V. Yanilkin; Янилкин И. В.; A. I. Gumarov; Гумаров А. И.; A. V. Petrov; Петров А. В.; L. R. Tagirov; Тагиров Л. Р.; R. V. Yusupov; Юсупов Р. В.

doi:10.31857/S0367676524070112

Synthesis, magnetic properties, and modelling of remagnetization of an artificial antiferromagnet based on L1₀-PdFe

Autores: Pasynkov M.V.¹, Yanilkin I.V.¹, Gumarov A.I.¹, Petrov A.V.¹, Tagirov L.R.¹^,2, Yusupov R.V.¹
Afiliações:
1. Kazan Federal University
2. Federal Research Сenter Kаzаn Sсientifiс Сenter оf the Russian Аcademy of Sciences
Edição: Volume 88, Nº 7 (2024)
Páginas: 1072-1076
Seção: Spin physics, spin chemistry and spin technologies
URL: https://kld-journal.fedlab.ru/0367-6765/article/view/676737
DOI: https://doi.org/10.31857/S0367676524070112
EDN: https://elibrary.ru/PBDUHP
ID: 676737

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We presented the results of experimental studies of static magnetic properties and modeling of magnetization reversal in an epitaxial thin film of the L1₀-phase of the PdFe compound and the PdFe/W/PdFe heterostructure on MgO (001) substrates. It is shown that the PdFe/W/PdFe heteroepitaxial structure with the α-W layer thickness of ~ 0.7 nm represents an artificial antiferromagnet with perpendicular magnetic anisotropy and an exchange integral value of $J ≃ 1.7 \cdot 10^{- 3} Д ж / м^{2}$ . Micromagnetic modeling of the equilibrium domain structure and its evolution in an external magnetic field made it possible to satisfactorily describe the magnetization reversal curve of the studied thin-film heterostructure.

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synthetic antiferromagnet, L10 phase, perpendicular anisotropy, micromagnetic modeling

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Rússia, Kazan

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Chappert C., Fert A., Van Dau F.N. // Nature Mater. 2007. V. 6. No.11. P. 813.
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Воронин К.В., Лобанов И.С., Уздин В.М. // Письма в ЖЭТФ. 2022. Т. 116. № 3—4. С. 242; Voronin K.V., Lobanov I.S., Uzdin V.M. // JETP Lett. 2022. V. 116. No. 3—4. P. 240.
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2. Fig. 1. Magnetization reversal curve of a single thin epitaxial film of the L10 phase of the PdFe compound in a field applied normally to the plane of the sample.

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3. Fig. 2. Magnetization reversal curve of the thin-film epitaxial heterostructure PdFe/W/PdFe in a field applied along the normal (red symbols) and the result of its micromagnetic modeling (black curve).

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4. Fig. 3. Magnetization curves of a single thin PdFe film (shown in red) and a heteroepitaxial PdFe/W/PdFe structure (green curve), measured in a field lying in the plane of the samples.

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5. Fig. 4. Equilibrium domain structure of the thin-film heteroepitaxial FePd/W/FePd structure in zero magnetic field (a) and its evolution in an applied magnetic field (b). Two columns of panel (b) illustrate the distribution of the normal component of magnetization in the middle (throughout the thickness) of each of the two magnetic layers; black and white colors correspond to the directions of magnetization downward and upward along the normal to the plane of the sample, respectively.

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Synthesis, magnetic properties, and modelling of remagnetization of an artificial antiferromagnet based on L10-PdFe

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Sobre autores

Bibliografia

Arquivos suplementares

Synthesis, magnetic properties, and modelling of remagnetization of an artificial antiferromagnet based on L1₀-PdFe