Crystalline topological defects within response theory
Abstract
Crystal defects can highlight interesting quantum features by coupling to the low-energy Hamiltonian H. Here we show that independently of this H coupling, topological crystalline defects can generate new features by directly modifying the response theory of electric field probes such as Raman scattering. To show this we consider an antiferromagnetic spin-1/2 model Hspin on a zigzag chain. Crystalline domain walls between two zigzag domains appear as at most local defects in Hspin, but as topological (not locally creatable) defects in the Raman operator R of inelastic photon scattering. Using time evolving block decimation (TEBD) numerics, mean field, and bosonization, we show that a finite density of crystalline domain walls shifts the entire Raman signal to produce an effective gap. This lattice-defect-induced Raman gap closes and reopens in applied magnetic fields. We discuss the effect in terms of photons sensing the lattice defects within R as spin-dimerization domain walls, with Z2 character, and a resulting shift of the probed wavevector from q=0 to π+δ q, giving an O(1) change in contrast to local defects. The magneto-Raman singularity from topological lattice defects here relies on the Hspin spinon liquid state, suggesting future applications using lattice topological defects to modify response-theory operators independently of H and thereby generate new probes of quantum phases.
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