On the Symmetries of Anisotropic Spin Interaction Models

Abstract

We show that anisotropic spin interactions do not merely break spin-space group (SSG) symmetries, but instead twist them through cohomology invariants, yielding symmetry classes beyond subgroups of O(3)× Isom(R3) . This requires redefining the spin-only group S0 in terms of proper spin rotations. Based on this unitary S0, we formulate a twisted SSG (tSSG) theory that captures the complete set of spin-space symmetries. We then study a spin-1 model with tSSG symmetry using linear flavor wave theory and find topological quadrupolar excitations defined on a spin Brillouin Klein-bottle rather than the conventional torus. Specifically, the bosonic BdG Hamiltonian satisfies a glide reflection sewing relation, the ribbon spectrum exhibits Möbius boundary states. These topological excitations are classified by Z2 , enforced by the nonorientability of the Klein-bottle.