Magnetism and spin transport in platinum/scandium-substituted terbium iron garnet heterostructures

Abstract

Growth, structural, magnetic, and spin transport properties of epitaxial scandium-substituted terbium iron garnet (TbScIG) thin films on gadolinium gallium garnet [GGG, (111) orientation] substrates are reported as a function of Sc content. The films are epitaxial on GGG without strain relaxation up to a thickness of 90 nm and exhibit perpendicular magnetic anisotropy. Sc, a nonmagnetic cation, occupies up to 40% of the octahedral Fe sites. Increasing Sc lowers the compensation temperature and Curie temperature and increases the room-temperature saturation magnetization from 37 kA/m for ${\\mathrm{Tb}}_{2.8}{\\mathrm{Fe}}_{5.2}{\\mathrm{O}}_{12}$ to 59 kA/m for ${\\mathrm{Tb}}_{2.8}{\\mathrm{Sc}}_{0.8}{\\mathrm{Fe}}_{4.4}{\\mathrm{O}}_{12}$. Anomalous Hall effect-like spin Hall magnetoresistance measurements were performed to determine the effect of scandium content on spin mixing conductance of the TbScIG|Pt interface. The spin mixing conductance increased significantly with an increase in Sc content, consistent with a dependence of spin transport on the net Fe magnetization instead of the total magnetization of the garnet.