Multiferroicity with coexisting isotropic and anisotropic spins in Ca3Co2-xMnxO6

Abstract

We study magnetic and multiferroic behavior in Ca3Co2-xMnxO6 (x 0.97) by high-field measurements of magnetization (M), magnetostriction (L(H)/L), electric polarization (P), and magnetocaloric effect. This study also gives insight into the zero and low magnetic field magnetic structure and magnetoelectric coupling mechanisms. We measured M and /L up to pulsed magnetic fields of 92 T, and determined the saturation moment and field. On the controversial topic of the spin states of Co2+ and Mn4+ ions, we find evidence for S = 3/2 spins for both ions with no magnetic field-induced spin-state crossovers. Our data also indicate that Mn4+ spins are quasi-isotropic and develop components in the ab-plane in applied magnetic fields of 10 T. These spins cant until saturation at 85 T whereas the Ising Co2+ spins saturate by 25 T. Furthermore, our results imply that mechanism for suppression of electric polarization with magnetic fields near 10 T is flopping of the Mn4+ spins into the ab-plane, indicating that appropriate models must include the coexistence of Ising and quasi-isotropic spins.