Abstract
The effect of \mathcal{PT}𝒫𝒯-symmetry breaking in coupled systems with balanced gain and loss has recently attracted considerable attention and has been demonstrated in various photonic, electrical and mechanical systems in the classical regime. However, it is still an unsolved problem how to generalize the concept of \mathcal{PT}𝒫𝒯 symmetry to the quantum domain, where the conventional definition in terms of non-Hermitian Hamiltonians is not applicable. Here we introduce a symmetry relation for Liouville operators that describe the dissipative evolution of arbitrary open quantum systems. Specifically, we show that the invariance of the Liouvillian under this symmetry transformation implies the existence of stationary states with preserved and broken parity symmetry. As the dimension of the Hilbert space grows, the transition between these two limiting phases becomes increasingly sharp and the classically expected \mathcal{PT}𝒫𝒯-symmetry breaking transition is recovered. This quantum-to-classical correspondence allows us to establish a common theoretical framework to identify and accurately describe \mathcal{PT}𝒫𝒯-symmetry breaking effects in a large variety of physical systems, operated both in the classical and quantum regimes.
Highlights
The breaking of parity and time-reversal (PT ) symmetry has been widely studied in dissipative systems with an exact balance between gain and loss [1,2,3,4,5]
In this work we introduce a symmetry transformation for Liouville operators, which extends the conventional definition of PT symmetry to arbitrary open quantum systems
We have introduced the symmetry relation, Eq (4), for Liouville operators, which extends the notion of PT symmetry to bipartite open quantum systems
Summary
The breaking of parity and time-reversal (PT ) symmetry has been widely studied in dissipative systems with an exact balance between gain and loss [1,2,3,4,5]. In several previous studies this question has been addressed by looking at coupled quantum oscillators [17, 28,29,30,31, 34,35,36,37,38,39] or bosonic atoms [40] with gain and loss, or at equivalent coherent, but unstable systems [41] In such settings, the symmetry-breaking effect can still be observed in the dynamics of the mean amplitudes, which reproduce the classical equations of motion, while quantum effects lead to increased fluctuations. This quantum-toclassical correspondence allows us to establish a unified theoretical framework for analyzing PT -symmetry breaking effects in a wide range of physical systems and to identify characteristic properties and experimentally observable features that are common to all of them
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