Eigenstate thermalization hypothesis and eigenstate-to-eigenstate fluctuations

Abstract: We investigate the extent to which the eigenstate thermalization hypothesis~(ETH) is valid or violated in the non-integrable and the integrable spin-$1/2$ XXZ chain. We perform the energy-resolved analysis of the statistical properties of matrix elements ${O_{\gamma\alpha}}$ of an observable $\hat{O}$ in the energy eigenstate basis. The Hilbert space is coarse-grained into energy shells of width $\Delta_E$, with which one can define a block submatrix $\tilde{O}^{(b,a)}$ consisting of elements between eigenstates in the $a$th and $b$th shells. Each block submatrix is characterized by constant values of $E_{\gamma\alpha}=(E_\gamma+E_\alpha)/2 \simeq \tilde{E}$ and $\omega_{\gamma\alpha}= (E_\gamma-E_\alpha) \simeq \omega$ up to $\Delta_E$. We will show that all matrix elements within a block are statistically equivalent to each other in the non-integrable case. Their distribution is characterized by $\bar{E}$ and $\omega$, and follows the prediction of the ETH. In stark contrast, eigenstate-to-eigenstate fluctuations persist in the integrable case. Consequently, matrix elements $O_{\gamma\alpha}$ cannot be characterized by the energy parameters $E_{\gamma\alpha}$ and $\omega_{\gamma\alpha}$ only. Our result explains the origin for the breakdown of the fluctuation dissipation theorem in the integrable system. The eigenstate-to-eigenstate fluctuations sheds a new light on the meaning of the ETH.