Classical Simulability from Operator Entanglement Scaling
Abstract
Local-operator entanglement (LOE) quantifies the nonlocal structure of Heisenberg operators and serves as a diagnostic of many-body chaos. We provide rigorous bounds showing when an operator can be well-approximated by a matrix-product operator (MPO), given asymptotic scaling of its LOE -R\'enyi entropies. Specifically, we prove that a volume law scaling for implies that the operator cannot be approximated efficiently as an MPO while faithfully reproducing all expectation values. On the other hand, if we restrict to correlations over a relevant sub-class of (ensembles of) states, then logarithmic scaling of the entropies implies MPO simulability. This result covers a range of relevant quantities, including infinite temperature autocorrelation functions, out-of-time-ordered correlators, and average-case expectation values over ensembles of computational basis states. Beyond this regime, we provide numerical evidence together with a random matrix model to argue that this simulability result also typically holds for arbitrary states. Our results put on firm footing the heuristic expectation that a low operator entanglement implies efficient tensor network representability, extending celebrated foundational results from the theory of matrix-product states and providing a formal link between quantum chaos and classical simulability.
Keywords
Cite
@article{arxiv.2603.05656,
title = {Classical Simulability from Operator Entanglement Scaling},
author = {Neil Dowling},
journal= {arXiv preprint arXiv:2603.05656},
year = {2026}
}
Comments
6+11 pages, 2+2 figures. Comments welcome!