Mean field magnetism and spin frustration in a double perovskite oxide with compositional complexity
Abstract
The rise of high-entropy oxides as a major functional materials design principle in recent years has prompted us to investigate how compositional disorder affects long-range magnetic ordering in double perovskite oxides. Since ferromagnetic insulators are emerging as an important platform for lossless spintronics, we consider the RE2NiMnO6 (RE : rare-earth) family and investigate single-crystalline films of (La0.4Nd0.4Sm0.4Gd0.4Y0.4)NiMnO6 grown on SrTiO3 (001) substrates in this work. Despite configurational disorder and high cationic size variance at the RE site, the material exhibits robust ferromagnetic ordering with a Curie temperature (Tc) of approximately 150 K. This Tc is consistent with the expectation based on consideration of the average ionic radii of the rare-earth (RE) sites in the bulk RE2NiMnO6. Below Tc, Raman spectroscopy measurement finds a deviation from anharmonic behavior, where the phonon renormalization aligns with a mean-field approximation of spin-spin correlation. At lower temperature, magnetic RE ions also contributed to the magnetic behavior and the system displays a reentrant spin-glass-like behavior. This study demonstrates that while a mean-field approach serves as a viable starting point for predicting the long-range transition temperature, microscopic details of the complex magnetic interactions are essential for understanding the low-temperature phase.
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