Quantum coarse-grained entropy and thermalization in closed systems

Abstract: We investigate the detailed properties of Observational entropy, introduced by Šafránek et al. [Phys. Rev. A 99, 010101 (2019)] as a generalization of Boltzmann entropy to quantum mechanics. This quantity can involve multiple coarse-grainings, even those that do not commute with each other, without losing any of its properties. It is well-defined out of equilibrium, and for some coarse-grainings it generically rises to the correct thermodynamic value even in a genuinely isolated quantum system. The quantity co… Show more

“…To understand how this can increase in time, degrees of freedom are often coarse grained. It has been recently been shown [88,89] that this idea of coarse graining can be extended to quant um mechanics by making sequential observations of different observables. For example, one can observe coarse grained positional degrees of freedom and then energy.…”

Eigenstate thermalization hypothesis

“…To understand how this can increase in time, degrees of freedom are often coarse grained. It has been recently been shown [88,89] that this idea of coarse graining can be extended to quant um mechanics by making sequential observations of different observables. For example, one can observe coarse grained positional degrees of freedom and then energy.…”

Eigenstate thermalization hypothesis