Magnetic energy dissipative factors of spin-coated Y3Fe5O12 thin films

Y3Fe5O12 (YIG) is a ferrimagnetic insulator that shows significant potential in various applications such as spin pumping and optical devices. In the case of YIG, the uncompensated antiferromagnetic coupled Fe3+ ions originate the ferrimagnetic ordering. A homogeneous YIG thin film with lower Gilbert damping constant is essential for its industrial applications. Therefore, the YIG's intrinsic and extrinsic magnetic energy dissipative factors are crucial to explore. Here, we report the growth of uniform polycrystalline YIG thin films on thermally oxidized Si (100) substrates. X-ray diffraction confirms the single-phase formation of YIG. Surface morphology and thickness on thin films are studied using scanning electron microscopy. X-ray photoemission is used to probe the valence state of constituent elements of the ferrimagnetic thin films with saturation magnetization 3.11 mu s/f.u. The lowest Gilbert damping constant (a) = 4.754 x 10-3 with an inhomogeneous contribution to the linewidth of 5.04 mT is observed due to extrinsic inhomogeneous growth of the deposited films.

Automated summary

In this study, uniform polycrystalline YIG thin films were grown on thermally oxidized Si (100) substrates. X-ray diffraction confirmed the single-phase formation of YIG. Surface morphology and thickness of the thin films were examined using scanning electron microscopy. X-ray photoemission was used to investigate the valence state of constituent elements in the ferrimagnetic thin films with saturation magnetization of 3.11 mu s/f.u. The lowest Gilbert damping constant (a) = 4.754 x 10-3 with an inhomogeneous contribution to the linewidth of 5.04 mT was observed due to extrinsic inhomogeneous growth of the deposited films.