Lieb-Schultz-Mattis Theorem with Long-Range Interactions
Abstract
We prove the Lieb-Schultz-Mattis theorem in d-dimensional spin systems exhibiting SO(3) spin rotation and lattice translation symmetries in the presence of k-local interactions decaying as 1/rα with distance r. Two types of Hamiltonians are considered: Type I comprises long-range spin-spin couplings, while Type II features long-range couplings between SO(3) symmetric local operators. For spin-12 systems, it is shown that Type I cannot have a unique symmetric ground state with a nonzero excitation gap when the interaction decays sufficiently fast, when α>(3d,4d-2). For Type II, the condition becomes α>(3d-1,4d-3). In 1d, this ingappability condition is improved to α>2 for Type I and α>0 for Type II by examining the energy of a state with a uniform 2π twist. Notably, in 2d, a Type II Hamiltonian with van der Waals interaction is subject to the constraint of the theorem.
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