Complex interplay of magnetic ordering and spin-lattice coupling in orthochromite Nd0.5Dy0.5CrO3
Abstract
The mixed rare-earth orthochromite Nd0.5Dy0.5CrO3 has a N\'eel temperature (TN) of 175\,K, resulting in the G-type antiferromagnetic ordering of Cr3+ spins. The inverse susceptibility shows a deviation from Curie-Weiss law at 230\,K, with a large effective paramagnetic moment of 8.8\,μB. The ZFC-FC magnetization bifurcate just above TN and show a distinct signature of spin reorientation near 60\,K. Neutron diffraction show that below TN, the Cr3+ spins align in 2 representation as (Fx, Gz). Below 60\,K, due to spin reorientation, the magnetic structure is in 1 (Gy) configuration. The neutron diffraction does not show any signature of rare-earth ordering even at 1.5\,K. First principles density functional theory calculations within GGA+U and GGA+U+SO approximations reveal that the G-type antiferromagnetic order is the ground state magnetic structure of Cr sublattice and the spin-reorientation of Cr3+ spins can happen in the absence of 3d-4f interactions unlike in the case of orthoferrites. The specific heat shows a `λ' anomaly at TN, while at low temperature two distinct Schottky anomalies are observed; a Schottky peak at 2\,K and an additional step-like feature above 10\,K. Above TN, the magnetic transition is preceded by structural anomalies as seen in our x-ray diffraction and Raman measurements. The deviation of structural parameters near N\'eel temperature is smaller. The phonon frequencies show deviation from the standard anharmonic behaviour: first near 250\,K, due to magneto-volume effects while the second deviation occurs near 200\,K due to spin-phonon coupling.
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