Spin and lattice dynamics at the spin-reorientation transitions in the rare-earth orthoferrite Sm0.55Tb0.45FeO3
Abstract
Linear and non-linear couplings of magnetic and lattice excitations are at the heart of many fascinating magnetophononic phenomena observed in rare-earth orthoferrites, the distinctive feature of which is the tendency to spin-reorientation transitions. Here we report the results of the experimental study of the spin and lattice dynamics in the Brillouin zone center of the rare-earth orthoferrite Sm0.55Tb0.45FeO3 by using polarized infrared reflectivity and Raman scattering spectroscopic techniques. The obtained results were supported by the first-principles calculations, which allowed us to reliably identify the parameters of most infrared- and Raman-active phonons. We reveal the spin-reorientation transitions 4(GaFc) T1 24(GacFac) T2 2(GcFa) at T1 220 K and T2 130 K and carefully studied the following evolution of Raman scattering on magnetic excitations at these transitions. Notably, the intermediate magnetic structure 24 displays an exceptionally broad temperature range T = T1 - T2 90 K in mixed Sm0.55Tb0.45FeO3 compared to pure rare-earth orthoferrites. We attribute this broadening of the intermediate phase to the modification of the magnetocrystalline anisotropy as a result of the inhomogeneous magnetic structure caused by the random distribution of rare-earth Sm3+ and Tb3+ ions. We found neither change in the parameters of Raman-active B1g phonons nor the appearance of new phonons induced by spin-reorientation transitions, which have been reported in SmFeO3. We assume that our results provide a solid basis for more deeper understanding of magnetophononic phenomena in rare-earth orthoferrites.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.