Lieb-Robinson bounds with exponential-in-volume tails

Abstract

Lieb-Robinson bounds demonstrate the emergence of locality in many-body quantum systems. Intuitively, Lieb-Robinson bounds state that with local or exponentially decaying interactions, the correlation that can be built up between two sites separated by distance r after a time t decays as (vt-r), where v is the emergent Lieb-Robinson velocity. In many problems, it is important to also capture how much of an operator grows to act on rd sites in d spatial dimensions. Perturbation theory and cluster expansion methods suggest that at short times, these volume-filling operators are suppressed as (-rd) at short times. We confirm this intuition, showing that for r > vt, the volume-filling operator is suppressed by (-(r-vt)d/(vt)d-1). This closes a conceptual and practical gap between the cluster expansion and the Lieb-Robinson bound. We then present two very different applications of this new bound. Firstly, we obtain improved bounds on the classical computational resources necessary to simulate many-body dynamics with error tolerance ε for any finite time t: as ε becomes sufficiently small, only ε-O(td-1) resources are needed. A protocol that likely saturates this bound is given. Secondly, we prove that disorder operators have volume-law suppression near the "solvable (Ising) point" in quantum phases with spontaneous symmetry breaking, which implies a new diagnostic for distinguishing many-body phases of quantum matter.

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