Higher-Order Krylov State Complexity in Random Matrix Quenches
Abstract
In quantum many-body systems, time-evolved states typically remain confined to a smaller region of the Hilbert space known as the . The time evolution can be mapped onto a one-dimensional problem of a particle moving on a chain, where the average position defines Krylov state complexity or spread complexity. Generalized spread complexities, associated with higher-order moments for , provide finer insights into the dynamics. We investigate the time evolution of generalized spread complexities following a quantum quench in random matrix theory. The quench is implemented by transitioning from an initial random Hamiltonian to a post-quench Hamiltonian obtained by dividing it into four blocks and flipping the sign of the off-diagonal blocks. This setup captures universal features of chaotic quantum quenches. When the initial state is the thermofield double state of the post-quench Hamiltonian, a peak in spread complexity preceding equilibration signals level repulsion, a hallmark of quantum chaos. We examine the robustness of this peak for other initial states, such as the ground state or the thermofield double state of the pre-quench Hamiltonian. To quantify this behavior, we introduce a measure based on the peak height relative to the late-time saturation value. In the continuous limit, higher-order complexities show increased sensitivity to the peak, supported by numerical simulations for finite-size random matrices.
Cite
@article{arxiv.2412.16472,
title = {Higher-Order Krylov State Complexity in Random Matrix Quenches},
author = {Hugo A. Camargo and Yichao Fu and Viktor Jahnke and Keun-Young Kim and Kuntal Pal},
journal= {arXiv preprint arXiv:2412.16472},
year = {2025}
}
Comments
31 pages, 9 figures; v2: tables updated with 10 realizations, figure 2 improved, reference added, discussions added for the physical meaning of the generalized complexity on Krylov chain, $r_n$ in figure 3 , and $r$-parameter when $h$ approaches $0$ in appendix C, match published version in JHEP