Abstract
Via the hierarchy of correlations, we study the strongly interacting Fermi-Hubbard model in the Mott insulator state and couple it to a Markovian environment which constantly monitors the particle numbers $\hat n_\mu^\uparrow$ and $\hat n_\mu^\downarrow$ for each lattice site $\mu$. As expected, the environment induces an imaginary part $\gamma$ (i.e., decay rate) of the quasi-particle frequencies $\omega_{\mathbf{k}}\to\omega_{\mathbf{k}}-i\gamma$ and tends to diminish the correlations between lattice sites. Surprisingly, the environment does also steer the state of the system on intermediate time scales $\mathcal{O}(1/\gamma)$ to a pre-thermalized state very similar to a quantum quench (i.e., suddenly switching on the hopping rate $J$). Full thermalization occurs via local on-site heating and takes much longer.
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