Hedgehog lattice and field-induced chirality in breathing-pyrochlore Heisenberg antiferromagnets

Abstract

We theoretically investigate a J1-J3 classical Heisenberg model on the breathing pyrochlore lattice, where the nearest-neighbor (NN) exchange interactions for small and large tetrahedra, J1 and J1', take different values due to the breathing bond-alternation and J3 is the third NN antiferromagnetic interaction along the bond direction. It is found by means of Monte Carlo simulations that for large J3, a hedgehog lattice, a three-dimensional periodic array of magnetic monopoles and antimonopoles, emerges in the form of a quadruple- Q state characterized by the ordering vector of Q=(12,12,12), being irrespective of the signs of J1 and/or J1' as long as J1≠ J1'. It is also found that in an applied magnetic field, there appear six quadruple- Q states depending on the values of J1 and J1', among which three phases including the in-field hedgehog-lattice state exhibit nonzero total chirality T associated with the anomalous Hall effect of chirality origin. In the remaining two chiral phases, which are realized in the presence of ferromagnetic J1 and/or J1', the spin structure is not topologically nontrivial, in spite of the fact that T ≠ 0. The role of the topological objects of the monopoles in T is also discussed.