Magnetic-field induced effects on the electric polarization in RMnO3 (R = Dy, Gd)

TL;DR

This study investigates how magnetic fields influence the magnetic and electric properties of RMnO3 compounds, revealing field-induced reordering of spins and potential stabilization of ferroelectric phases.

Contribution

It provides new insights into magnetic field effects on rare earth manganites, showing how magnetic ordering reconfigurations can induce ferroelectricity.

Findings

Field-induced polarization enhancement in DyMnO3 due to Dy spin re-emergence

Confirmation of incommensurate Mn ordering with variable propagation vector

Magnetic field stabilizes cycloidal Mn ordering, inducing ferroelectricity

Abstract

X-ray resonant magnetic scattering studies of rare earth magnetic ordering were performed on perovskite manganites RMnO3 (R = Dy, Gd) in an applied magnetic field. The data reveal that the field-induced three-fold polarization enhancement for H || a (H approx. 20 kOe) observed in DyMnO3 below 6.5 K is due to a re-emergence of the Mn-induced Dy spin order with propagation vector k(Dy) = k(Mn) = 0.385 b*, which accompanies the suppression of the independent Dy magnetic ordering, k(Dy) = 1/2 b*. For GdMnO3, the Mn-induced ordering of Gd spins is used to track the Mn-ordering propagation vector. The data confirm the incommensurate ordering reported previously, with k(Mn) varying from 0.245 to 0.16 b* on cooling from T_N(Mn) down to a transition temperature T'. New superstructure reflections which appear below T' suggest a propagation vector k(Mn) = 1/4 b* in zero magnetic field, which may coexist with the previously reported A-type ordering of Mn. The Gd spins order with the same propagation vector below 7 K. Within the ordered state of Gd at T = 1.8 K we find a phase boundary for an applied magnetic field H || b, H = 10 kOe, which coincides with the previously reported transition between the ground state paraelectric and the ferroelectric phase of GdMnO3. Our results suggest that the magnetic ordering of Gd in magnetic field may stabilize a cycloidal ordering of Mn that, in turn, produces ferroelectricity.