Quantum dynamics of disordered spin chains with power-law interactions

Abstract

We use extensive numerical simulations based on matrix product state methods to study the quantum dynamics of spin chains with strong on-site disorder and power-law decaying (1/rα) interactions. We focus on two spin-1/2 Hamiltonians featuring power-law interactions: Heisenberg and XY and characterize their corresponding long-time dynamics using three distinct diagnostics: decay of a staggered magnetization pattern I(t), growth of entanglement entropy S(t), and growth of quantum Fisher information FQ(t). For sufficiently rapidly decaying interactions α>αc we find a many-body localized phase, in which I(t) saturates to a non-zero value, entanglement entropy grows as S(t) t1/α, and Fisher information grows logarithmically. Importantly, entanglement entropy and Fisher information do not scale the same way (unlike short range interacting models). The critical power αc is smaller for the XY model than for the Heisenberg model.