Nature of the field-induced magnetic incommensurability in multiferroic Ni3TeO6

Abstract

Using single crystal neutron scattering we show that the magnetic structure Ni3TeO6 at fields above 8.6 T along the c axis changes from a commensurate collinear antiferromagnetic structure with spins along c and ordering vector QC= (0 0 1.5), to a conical spiral with propagation vector QIC= (0 0 1.5δ),δ0.18, having a significant spin component in the (a,b) plane. We determine the phase diagram of this material in magnetic fields up to 10.5 T along c and show the phase transition between the low field and conical spiral phases is of first order by observing a discontinuous jump of the ordering vector. QIC is found to drift both as function of magnetic field and temperature. Preliminary inelastic neutron scattering reveals that the spin wave gap in zero field has minima exactly at QIC and a gap of about 1.1 meV consisting with a cross-over around 8.6 T. Our findings excludes the possibility of the inverse Dzyaloshinskii-Moriya interaction as a cause for the giant magneto-electric coupling earlier observed in this material and advocates for the symmetric exchangestriction as the origin of this effect.