Energy-filtered quantum states and the emergence of non-local correlations

Energy-filtered quantum states are promising candidates for efficiently simulating thermal states. We explore a protocol designed to transition a product state into an eigenstate located in the middle of the spectrum; this is achieved by gradually reducing its energy variance, which allows us to comprehensively understand the crossover phenomenon and the subsequent convergence towards thermal behavior. We introduce and discuss three energy-filtering regimes (short, medium and long), and we interpret them as stages of thermalization. We show that the properties of the filtered states are locally indistinguishable from those of time-averaged density matrices, routinely employed in the theory of thermalization. On the other hand, unexpected non-local quantum correlations are generated in the medium regimes and are witnessed by the R\'enyi entanglement entropies of subsystems, which we compute via replica methods. Specifically, two-point correlation functions break cluster decomposition and the entanglement entropy of large regions scales as the logarithm of the volume during the medium filter time.