Reentrant spin reorientation transition and Griffiths-like phase in antiferromagnetic TbFe0.5Cr0.5O3

Abstract

The perovskite TbFe0.5Cr0.5O3 shows two anomalies in the magnetic susceptibility at TN = 257K and TSR = 190K which are respectively, the antiferromagnetic and spin reorientation transition that occur in the Fe/Cr sublattice. Analysis of the magnetic susceptibility reveals signatures of Griffiths-like phase in this compound. Neutron diffraction analysis confirms that, as the temperature is reduced from 350K, a spin reorientation transition from 2 (Fx, Cy, Gz) to 4 (Gx, Ay, Fz) occurs at TN = 257K and subsequently, a second spin reorientation takes place from 4 (Gx, Ay, Fz) to 2 (Fx, Cy, Gz) at TSR = 190K. The 2 (Fx, Cy, Gz) structure is stable until 7.7K where an ordered moment of 7.74(1)μ B/Fe3+(Cr3+) is obtained from neutron data refinement. In addition to the long-range order of the magnetic structure, indication of diffuse magnetic scattering at 7.7K is evident, thereby lending support to the Griffiths-like phase observed in susceptibility. At 7.7K, Tb develops a ferromagnetic component along the crystallographic a axis. Thermal conductivity, and spin-phonon coupling of TbFe0.5Cr0.5O3 through Raman spectroscopy are studied in the present work. An antiferromagnetic structure with ( ) arrangement of Fe/Cr spins is found in the ground state through first-principles energy calculations which supports the experimental magnetic structure at 7.7K. The spin-resolved total and partial density of states are determined showing that TbFe0.5Cr0.5O3 is insulating with a band gap of 0.12 (2.4) eV within GGA (GGA+U) functionals.