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arxiv: 1904.03473 · v2 · pith:CD25KKGV · submitted 2019-04-06 · cond-mat.stat-mech · math-ph· math.MP· physics.class-ph· quant-ph

Entropy non-conservation and boundary conditions for Hamiltonian dynamical systems

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classification cond-mat.stat-mech math-phmath.MPphysics.class-phquant-ph
keywords boundaryentropyclassicalconditionsquantumsystemsystemsdistributions
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Applying the theory of self-adjoint extensions of Hermitian operators to Koopman von Neumann classical mechanics, the most general set of probability distributions is found for which entropy is conserved by Hamiltonian evolution. A new dynamical phase associated with such a construction is identified. By choosing distributions not belonging to this class, we produce explicit examples of both free particles and harmonic systems evolving in a bounded phase-space in such a way that entropy is nonconserved. While these nonconserving states are classically forbidden, they may be interpreted as states of a quantum system tunneling through a potential barrier boundary. In this case, the allowed boundary conditions are the only distinction between classical and quantum systems. We show that the boundary conditions for a tunneling quantum system become the criteria for entropy preservation in the classical limit. These findings highlight how boundary effects drastically change the nature of a system.

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