A Strategy for Enhancing Perpendicular Magnetic Anisotropy in Yttrium Iron Garnet Films

In future information storage and processing, magnonics is one of the most promising candidates to replace traditional microelectronics. Yttrium iron garnet (YIG) films with perpendicular magnetic anisotropy (PMA) have aroused widespread interest in magnonics. Obtaining strong PMA in a thick YIG film with a small lattice mismatch (eta) has been fascinating but challenging. Here, a novel strategy is proposed to reduce the required minimum strain value for producing PMA and increase the maximum thickness for maintaining PMA in YIG films by slight oxygen deficiency. Strong PMA is achieved in the YIG film with an eta of only 0.4% and a film thickness up to 60 nm, representing the strongest PMA for such a small eta reported so far. Combining transmission electron microscopy analyses, magnetic measurements, and a theoretical model, it is demonstrated that the enhancement of PMA physically originates from the reduction of saturation magnetization and the increase of magnetostriction coefficient induced by oxygen deficiency. The Gilbert damping values of the 60-nm-thick YIG films with PMA are on the order of 10-4. This strategy improves the flexibility for the practical applications of YIG-based magnonic devices and provides promising insights for the theoretical understanding and the experimental enhancement of PMA in garnet films. A strategy is proposed for achieving strong perpendicular magnetization anisotropy (PMA) in the yttrium iron garnet (YIG) film with a lattice mismatch of only 0.4% and a thickness up to 60 nm through slight oxygen deficiency, marking the strongest PMA for such a small mismatch. Relevant theoretical analyses are employed to elucidate the intrinsic physical mechanism. image