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内容記述 |
Compositionally graded profiles of a substituent element artificially introduced into a complex oxide can offer a viable route to decouple and retune physical properties in a trade-off relationship caused by uniform substitution. Here, this is demonstrated with particular attention to the magnetism in Ru-substituted LSMO ((La,Sr)(Mn,Ru)O3) epitaxial films with the Ru composition linearly increasing (UP-graded) or decreasing (DOWN-graded) along the growth direction. A combination of macroscopic magnetometry and depth-resolved polarized neutron reflectometry (PNR) allows for the magnetism of surface/interface and the in-between bulk layer to be separately discussed to reveal how the introduction of a composition gradient has solved the trade-off among Curie temperature (TC), saturation magnetization (Ms), and coercivity (Hc) in Ru-substituted LSMO. Macroscopically graded films exhibit as much enhancement in Hc as the corresponding uniformly substituted films, with TC and Ms, which otherwise will be monotonically reduced, being maintained as high as the unsubstituted film. In an UP-graded film, the surface and interface magnetization is more strongly suppressed than that in the uniformly substituted films, while the Ms in the in-between bulk layer is found to be microscopically graded according to the local Ru composition. Importantly, despite the suppression in magnetization at the interface and surface, each local magnetization in the in-between bulk layer is higher than that of its uniform counterpart. As a result, the UP-graded LSMO yields higher magnetization than the corresponding uniformly substituted film, consistent with the macroscopic magnetometry result. Bulk-sensitive Mn L2,3-edge fluorescence-yield X-ray magnetic circular dichroism (XMCD) of the UP-graded film further provides evidence that the Mn spin sublattice is genuinely responsible for the magnetic enhancement by the Ru composition gradient. The present successful balancing of TC, Ms, and Hc in LSMO will reinforce the possibility of LSMO as a spintronic oxide material, encouraging further exploration of potential applications of the compositionally graded profiling approach in other related oxide systems. |
