Vortex order in magnetic frustrated GeNi2O4 and GeCo2O4 spinels

Abstract

In the search for new spin textures based on singular magnetic objects like Bloch-points or vortices, spinel compounds emerge as an interesting playground due to the interplay between magnetic anisotropy and complex interactions that extend well beyond first neighbors on a pyrochlore lattice. Based on an exploration of the exchange interaction phase diagrams of members of the GeB2O4 family with B=Co and Ni, we show, using simultaneous modeling of inelastic neutron scattering measurements and single-crystal neutron diffraction data, that a 2-k magnetic structure may be stabilized in these compounds. This leads to a short period spin vortex crystal, a variant induced by the magnetic anisotropy of the 3-k Bloch-point structure predicted for isotropic spins. Our study rationalizes the formation of these multi-k spin textures in frustrated antiferromagnets, as well as their anisotropy-dependent evolution.