Unraveling the mechanisms responsible for perpendicular magnetic anisotropy (PMA) in amorphous rare earth-transition metal alloys has proven challenging, primarily due to the intrinsic complexity of the amorphous structure. Here, we investigated the atomic origin of PMA by applying an approach of voltage-driven hydrogen insertion in interstitial sites, which serve as a perturbation and probe in local atomic structure. After hydrogen charging, PMA in amorphous TbCo thin films diminished and switched to in-plane anisotropy, accompanied by distinct magnetic domain structures. By analyzing the mechanism behind the anisotropy switching, we unveiled the decisive role of Tb-Co/Tb-Tb bonding in shaping the magnetic anisotropy using both angle-dependent X-ray magnetic dichroism and ab initio calculations. Hydrogen insertion induced a reorientation of the local anisotropy axis, initially along the Tb-Co bonding direction, due to the distortion of crystal field around Tb. Our approach not only shows the atomic origin of Tb-Co bonding in inducing PMA, but also enables the voltage-driven tailoring of magnetic anisotropy in amorphous alloys.
Comment: 4 pages, 4 figures in manuscript. Supplementary materials in total 17 pages