Successive spin reorientation and rare earth ordering in Nd0.5Dy0.5FeO3: Experimental and Ab-initio investigations

Abstract

In present study, the magnetic structure and spin reorientation of mixed doped orthoferrite Nd0.5Dy0.5FeO3 have been investigated. Similar to both parent compounds (NdFeO3 and DyFeO3), the magnetic structure of Fe3+ belongs to 4 irreducible representation (Gx, Fz) at room temperature. The experimental measurements confirmed the spin reorientation where magnetic structure of Fe3+ changes from 4 to 2(Fx, Gz) between 75 and 20 \,K while maintaining G-type configuration. Such a gradual spin reorientation is unusual since the large single ion anisotropy of Dy3+ ions causes an abrupt 4→ 1(Gy) spin reorientation in DyFeO3. Between 20 and 10 \,K, the Fe3+ magnetic structure is represented by 2 (Fx, Gz). Unexpectedly, magnetic structure of Fe3+ with 4 representation re-emerges below 10\,K which also coincides with the development of rare-earth (Nd3+/Dy3+) magnetic ordering having Cy configuration with magnetic moment of 1.8 μB. The absence of any signature of second order phase transition in the specific heat confirms the role of R(Nd3+/Dy3+)-Fe3+ exchange interaction in the observed "rare-earth ordering" unlike DyFeO3 where Dy3+ ordering takes place independently to the magnetic ordering of Fe3+ magnetic structure. Our (DFT+U+SO) calculations show that the C-type arrangement of rare-earth ions (Nd3+/Dy3+) with 2 configuration for Fe3+ moments is the ground state whereas 4 phase is energetically very close. Nd-Fe and Nd-Dy exchange interactions, estimated from DFT, are observed to have significant roles in the rare earth ordering and Fe spin reorientation corroborating our experimental results.