Abstract
We consider growth of local operators under Euclidean time evolution in lattice systems with local interactions. We derive rigorous bounds on the operator norm growth and then proceed to establish an analog of the Lieb-Robinson bound for the spatial growth. In contrast to the Minkowski case when ballistic spreading of operators is universal, in the Euclidean case spatial growth is system-dependent and indicates if the system is integrable or chaotic. In the integrable case, the Euclidean spatial growth is at most polynomial. In the chaotic case, it is the fastest possible: exponential in 1D, while in higher dimensions and on Bethe lattices local operators can reach spatial infinity in finite Euclidean time. We use bounds on the Euclidean growth to establish constraints on individual matrix elements and operator power spectrum. We show that one-dimensional systems are special with the power spectrum always being superexponentially suppressed at large frequencies. Finally, we relate the bound on the Euclidean growth to the bound on the growth of Lanczos coefficients. To that end, we develop a path integral formalism for the weighted Dyck paths and evaluate it using saddle point approximation. Using a conjectural connection between the growth of the Lanczos coefficients and the Lyapunov exponent controlling the growth of OTOCs, we propose an improved bound on chaos valid at all temperatures.
Highlights
AND RESULTSOperator spreading, or growth, in local systems is a question of primary interest, which encodes transport properties, emergence of chaos and other aspects of many-body quantum dynamics [1,2,3,4,5,6,7,8]
Using a conjectural connection between the growth of the Lanczos coefficients and the Lyapunov exponent controlling the growth of the out-of-time-ordered correlators (OTOCs), we propose an improved bound on chaos valid at all temperatures
We find that maximal rate of growth is very different in 1D, where it is at most double-exponential, and in higher dimensions or Bethe lattices, where the norm can become infinite in finite Euclidean time
Summary
Growth, in local systems is a question of primary interest, which encodes transport properties, emergence of chaos and other aspects of many-body quantum dynamics [1,2,3,4,5,6,7,8]. We find that maximal rate of growth is very different in 1D, where it is at most double-exponential, and in higher dimensions or Bethe lattices, where the norm can become infinite in finite Euclidean time. The bound on |A(−iβ )| can be translated into a bound on the growth of Lanczos coefficients bn, appearing as a part of the recursion method to numerically compute CT (t ) This is provided we assume that asymptotically bn is a smooth function of n.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
