A measure of chaos from eigenstate thermalization hypothesis

Nilakash Sorokhaibam

Published 2024-01-24Version 1

Eigenstate thermalization hypothesis is a detailed statement of the matrix elements of few-body operators in energy eigenbasis of a chaotic Hamiltonian. Part of the statement is that the off-diagonal elements fall exponential for large energy difference. We propose that the exponent ($\gamma>0$) is a measure of quantum chaos. Smaller $\gamma$ implies more chaotic dynamics. The chaos bound is given by $\gamma=\beta/4$ where $\beta$ is the inverse temperature. We give analytical argument in support of this proposal. The slower exponential fall also means that the action of the operator on a state leads to higher delocalization in energy eigenbasis. Numerically we compare two chaotic Hamiltonians - SYK model and chaotic XXZ spin chain. Using the new measure, we find that the SYK model becomes maximally chaotic at low temperature which has been shown rigorously in previous works. The new measure is more readily accessible compare to other measures using numerical methods.