English

Operator Krylov complexity in random matrix theory

High Energy Physics - Theory 2024-01-01 v1 Quantum Gases Statistical Mechanics Strongly Correlated Electrons

Abstract

Krylov complexity, as a novel measure of operator complexity under Heisenberg evolution, exhibits many interesting universal behaviors and also bounds many other complexity measures. In this work, we study Krylov complexity K(t)\mathcal{K}(t) in Random Matrix Theory (RMT). In large NN limit: (1) For infinite temperature, we analytically show that the Lanczos coefficient {bn}\{b_n\} saturate to constant plateau limnbn=b\lim\limits_{n\rightarrow\infty}b_n=b, rendering a linear growing complexity K(t)t\mathcal{K}(t)\sim t, in contrast to the exponential-in-time growth in chaotic local systems in thermodynamic limit. After numerically comparing this plateau value bb to a large class of chaotic local quantum systems, we find that up to small fluctuations, it actually bounds the {bn}\{b_n\} in chaotic local quantum systems. Therefore we conjecture that in chaotic local quantum systems after scrambling time, the speed of linear growth of Krylov complexity cannot be larger than that in RMT. (2) For low temperature, we analytically show that bnb_n will first exhibit linear growth with nn, whose slope saturates the famous chaos bound. After hitting the same plateau bb, bnb_n will then remain constant. This indicates K(t)e2πt/β\mathcal{K}(t)\sim e^{2\pi t/\beta} before scrambling time tO(βlogβ)t_*\sim O(\beta\log\beta), and after that it will grow linearly in time, with the same speed as in infinite temperature. We finally remark on the effect of finite NN corrections.

Cite

@article{arxiv.2312.17416,
  title  = {Operator Krylov complexity in random matrix theory},
  author = {Haifeng Tang},
  journal= {arXiv preprint arXiv:2312.17416},
  year   = {2024}
}

Comments

25 pages, 6 figures

R2 v1 2026-06-28T14:04:18.103Z