4.6 Article

Microstructure and Magnetic Anisotropy of SmCo-Based Films Prepared via External Magnetic Field Assisted Magnetron Sputtering

Journal

ADVANCED ENGINEERING MATERIALS
Volume 25, Issue 5, Pages -

Publisher

WILEY-V C H VERLAG GMBH
DOI: 10.1002/adem.202101456

Keywords

magnetic anisotropy; magnetic field assisted magnetron sputtering; micromagnetic simulations; SmCo-based films

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This paper presents the preparation of SmCo-based thin films using magnetic field assisted magnetron sputtering and rapid thermal annealing. By decreasing in-plane magnetic anisotropy and increasing out-of-plane coercivity, the magnetic properties of the films are improved. Micromagnetic simulations confirm the significance of the proportion of magnetic moment direction in controlling magnetic anisotropy and coercivity.
SmCo-based thin films have excellent permanent magnetic properties for application in magnetic functional devices. The conventional methods to control the magnetic anisotropy are inserting the suitable buffer layer or applying magnetic field heat treatment. However, the selection of the buffer layer and the thickness of the SmCo layer are limited. Additionally, the magnetic field heat treatment is detrimental to suppressing the grain growth. Herein, the SmCo-based thin films by magnetic field assisted magnetron sputtering followed by a rapid thermal annealing (RTA) is prepared. The characteristic diffraction peak of SmCo5 (200) with in-plane orientation disappears, indicating that the in-plane magnetic anisotropy could be further decreased. Meanwhile, the out-of-plane coercivity highly increases when applying an external magnetic field, which is contributed partly by the refined SmCo grains under the external magnetic field due to the reduction of critical free energy of Sm-Co cluster nucleation. Furthermore, micromagnetic simulations indicates that the out-of-plane magnetic moments of Sm2Co17 phase are more difficult to reverse because the ratio of in-plane and out-of-plane oriented moments changed from 1:1 to 1:1.4, and proves that the proportion of magnetic moment direction is significant to control magnetic anisotropy and coercivity which is consistent with the experiment results.

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