Magnetic structure and magnetoelectric properties of the spin-flop phase in LiFePO

Holm-Janas, S.*; 赤木 暢*; Fogh, E.*; 木原 工*; Le, M. D.*; Forino, P. C.*; Nikitin, S. E.*; Fennell, T.*; Painganoor, A.*; Vaknin, D.*; 渡辺 真朗   ; Christensen, N. B.*; 野尻 浩之*; Toft-Petersen, R.*

Holm-Janas, S.*; Akaki, Mitsuru*; Fogh, E.*; Kihara, Takumi*; Le, M. D.*; Forino, P. C.*; Nikitin, S. E.*; Fennell, T.*; Painganoor, A.*; Vaknin, D.*; Watanabe, Masao; Christensen, N. B.*; Nojiri, Hiroyuki*; Toft-Petersen, R.*

We investigate the magnetic structure and magnetoelectric (ME) effect in the high-field phase of the antiferromagnet LiFePO above the critical field of 31 T. A neutron diffraction study in pulsed magnetic fields reveals the propagation vector to be q = 0 for the high-field magnetic structure. In addition, neutron diffraction measurements in low magnetic fields show no observable field-induced spin canting, which indicates negligible Dzyaloshinskii-Moriya interaction. The observed spin-flop field supports the Hamiltonian recently deduced from inelastic neutron studies and indicates that the system is less frustrated and with a larger single-ion anisotropy than originally thought. Our results demonstrate the effectiveness of combining pulsed-field neutron diffraction and electric polarization measurements to elucidate the magnetic structures and symmetries at the highest attainable field strengths.