Recurrence Theorem for Open Quantum Systems

Quantum (Poincar\'e) recurrence theorem are known for closed quantum (classical) systems. Can recurrence happen in open systems? We provide the recurrence theorem for open quantum systems via non-Hermitian (NH) description. We find that PT symmetry and pseudo-Hermitian symmetry protect recurrence for NH open quantum systems and the recurrence fails with the symmetry breaking. Applying our theorem to PT-symmetric systems, we reveal why quantum recurrence happens in PT-unbroken phase but fails in PT-broken phase, which was misunderstood before. A contradiction emerges when we apply our theorem to anti-PT symmetric systems and we settle it, revealing that distinguishability and von Neumann entropy are generally not effective to describe the information dynamics in NH systems. A new approach is developed to investigate the information dynamics of NH systems. For anti-PT symmetric systems in PT-broken phase, we find there are three information-dynamics patterns: oscillations with an overall decrease (increase) , and periodic oscillations. The periodic oscillations (information complete retrieval) happen only if the spectrum of NH Hamiltonian is real. The three patterns degenerate to the periodic oscillation using distinguishability or von Neumann entropy because normalization of non-unitary evolved states leads to loss of information. We conclude with a discussion of the physical meaning behind the recurrence in open systems and give the direction of recurrence theorem not limited to conservative systems in classical mechanics.