Journal
IEEE TRANSACTIONS ON MAGNETICS
Volume 57, Issue 2, Pages -Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TMAG.2020.3005599
Keywords
Antiferromagnetic coupling; insert layer; interface; magnetic proximity effect (MPE); spin damping
Funding
- National Key Research and Development Program of China [2017YFA0204800]
- National Nature Science Foundation of China (NSFC) [51571062, 61427812, 11504047]
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The magnetic dynamic behaviors of permalloy films capped with gadolinium were studied, with the effects of increasing Gd thickness decreasing the saturation magnetization and surface anisotropy constant while enhancing the Gilbert damping. The introduction of a copper insert at the interface suppressed these trends, attributed to antiferromagnetic coupling between Gd and Py near the interface caused by the magnetic proximity effect.
Magnetic dynamic damping is significantly important in determining the relaxation time of magnetic moments and the speed of magnetic memory devices. Here, magnetic dynamic behaviors of permalloy (Py) films capped with gadolinium (Gd) are studied, and the effects of the interface are investigated by the Cu insert layer. For Py/Gd bilayer films, both the saturation magnetization (M-s) and the surface anisotropy constant (K-perpendicular to) are decreased with increasing Gd thickness, while the Gilbert damping (alpha) is enhanced. With the insert of Cu at Py/Gd interface, the above tendencies of M-s, K-perpendicular to, and alpha are suppressed. We attribute these phenomena to the antiferromagnetic coupling between Gd and Py near the interface, which are caused by the magnetic proximity effect (MPE) instead of the spin relaxation in the rare earth Gd themselves.
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