Stress-Enhanced Interlayer Exchange Coupling and Optical-Mode FMR Frequency in Self-Bias FeCoB/Ru/FeCoB Trilayers

• Published in: ACS applied materials & interfaces Vol. 10; no. 10; pp. 8853 - 8859
• Main Authors: Li, Shandong, Miao, Guo-Xing, Cao, Derang, Li, Qiang, Xu, Jie, Wen, Zheng, Dai, Youyong, Yan, Shishen, Lü, Yueguang
• Format: Journal Article
• Language: English
• Published: United States American Chemical Society 14.03.2018
• Subjects: acoustics; anisotropy; engineering; ferrimagnetic materials; films (materials); magnetism; stress response; interlayer exchange coupling; uniaxial stress; optical-mode FMR; ferromagnetic resonance; antiferromagnetic coupling
• ISSN: 1944-8244; 1944-8252; 1944-8252
• DOI: 10.1021/acsami.7b19684

Nowadays, the most popular method to increase ferromagnetic resonance (FMR) frequency (f r) in self-bias soft magnetic films is to improve the anisotropy field H K. However, to push f r to higher frequencies only via raising H K becomes increasingly challenging because f r is already higher than 10 GHz by now. In this study, we fabricated a series of magnetically anisotropic FeCoB/Ru/FeCoB sandwich films possessing antiferromagnetic-like coupling and gradually increased uniaxial stress in the FeCoB sublayers from 52 to 110 MPa. It is quite remarkable that the acoustic mode of FMR gradually disappears, whereas the optical mode is enhanced in these structures. We observed simultaneous enhancement of H K and interlayer coupling field (J IEC) with the uniaxial stress, which leads to a very pronounced optical-mode frequency increase from 8.67 to 11.62 GHz with a very sensitive stress response of 51 Hz/Pa. In contrast, the f r in a FeCoB single layer (acoustic mode) only varies from 3.47 to 5.05 GHz under similar stress. We believe that the strain-induced electron density variation of the Ru spacer’s Fermi surface in the out-of-plane direction is responsible for the enhancement of J IEC. This study demonstrates that the antiferromagnetic coupling is a new route to achieve higher f r and provides the possibility of engineering and manipulating optical-mode resonance simply by controlling the interlayer coupling strength via stress.