Real-time correlators in chaotic quantum many-body systems

Abstract

We study real-time local correlators (x,t)O(0,0) in chaotic quantum many-body systems. These correlators show universal structure at late times, determined by the dominant operator-space Feynman trajectories for the evolving operator O(x,t). The relevant trajectories involve the operator contracting to a point at both the initial and final time and so are structurally different from those dominating the out-of-time-order correlator. In the absence of conservation laws, correlations decay exponentially: (x,t)O(0,0)(-seq r(v) t), where v= x/ t defines a spacetime ray, and r(v) is an associated decay rate. We express r(v) in terms of cost functions for various spacetime structures. In 1+1D, operator histories can show a phase transition at a critical ray velocity vc, where r(v) is nonanalytic. At low v, the dominant Feynman histories are "fat": the operator grows to a size of order tα 1 before contracting to a point again. At high v the trajectories are "thin": the operator always remains of order-one size. In a Haar-random unitary circuit, this transition maps to a simple binding transition for a pair of random walks (the two spatial boundaries of the operator). In higher dimensions, thin trajectories always dominate. We discuss ways to extract the butterfly velocity vB from the time-ordered correlator, rather than the OTOC. Correlators in the random circuit may alternatively be computed with an effective Ising-like model: a special feature of the Ising weights for the Haar brickwork circuit gives vc=vB. This work addresses lattice models, but also suggests the possibility of morphological phase transitions for real-time Feynman diagrams in quantum field theories.

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