Magnetoelectric coupling tuned by competing anisotropies in Mn1-xNixTiO3

Abstract

A flop of electric polarization from P (Pc) to P (Pa) is observed in MnTiO3 as a spin flop transition is triggered by a c-axis magnetic field, H\|c=7 T. The critical magnetic field H\|c for Pa is significantly reduced in Mn1-xNixTiO3 (x=0.33). Pa and Pc have been observed with both H\|c and H\|a. Neutron diffraction measurements revealed similar magnetic arrangements for the two compositions where the ordered spins couple antiferromagnetically with their nearest intra- and inter-planar neighbors. In the x=0.33 system, the uniaxial and planar anisotropies of Mn2+ and Ni2+ compete and give rise to a spin reorientation transition at TR. A magnetic field, H\|c, aligns the spins along c for TR<T<TN. The rotation of the collinear spins away from the c-axis for T<TR alters the magnetic point symmetry and gives rise to a new ME susceptibility tensor form. Such linear ME response provides satisfactory explanation for the behavior of the field-induced electric polarization in both compositions. As the Ni content increases to x=0.5 and 0.68, the ME effect disappears as a new magnetic phase emerges.