English

Chaos, Complexity, and Random Matrices

High Energy Physics - Theory 2017-11-16 v2 Statistical Mechanics Quantum Physics

Abstract

Chaos and complexity entail an entropic and computational obstruction to describing a system, and thus are intrinsically difficult to characterize. In this paper, we consider time evolution by Gaussian Unitary Ensemble (GUE) Hamiltonians and analytically compute out-of-time-ordered correlation functions (OTOCs) and frame potentials to quantify scrambling, Haar-randomness, and circuit complexity. While our random matrix analysis gives a qualitatively correct prediction of the late-time behavior of chaotic systems, we find unphysical behavior at early times including an O(1)\mathcal{O}(1) scrambling time and the apparent breakdown of spatial and temporal locality. The salient feature of GUE Hamiltonians which gives us computational traction is the Haar-invariance of the ensemble, meaning that the ensemble-averaged dynamics look the same in any basis. Motivated by this property of the GUE, we introduce kk-invariance as a precise definition of what it means for the dynamics of a quantum system to be described by random matrix theory. We envision that the dynamical onset of approximate kk-invariance will be a useful tool for capturing the transition from early-time chaos, as seen by OTOCs, to late-time chaos, as seen by random matrix theory.

Keywords

Cite

@article{arxiv.1706.05400,
  title  = {Chaos, Complexity, and Random Matrices},
  author = {Jordan Cotler and Nicholas Hunter-Jones and Junyu Liu and Beni Yoshida},
  journal= {arXiv preprint arXiv:1706.05400},
  year   = {2017}
}

Comments

61 pages, 14 figures; v2: references added, typos fixed

R2 v1 2026-06-22T20:21:17.680Z