Abstract
The Pusey–Barrett–Rudolph (PBR) theorem deals with the realism of the quantum states. It establishes that every pure quantum state is real, in the context of quantum ontological models. Specifically, by guaranteeing the property of not-Post-Peierls (PP) compatibility (or antidistinguishability) for a particular set of states P, together with the ad hoc postulate known as preparation independence postulate (PIP), the theorem establishes that these two properties imply the ψ-onticity (realism) of the set of all pure states. This PBR result has triggered two particular lines of research: On the one hand, it has been possible to derive similar results without the use of the PIP, although at the expense of implying weaker properties than ψ-onticity. On the other hand, it has also been proven that the property of PP compatibility alone is an explicit witness of usefulness for the task known as conclusive exclusion of states. In this work, we explore the PP compatibility of the set of states P, when P is under the interaction of some noisy channels, which would consequently let us identify some noisy scenarios where it is still possible to perform the task of conclusive exclusion of states. Specifically, we consider the set P of n-qubit states in interaction with an environment by means of (i) individual and (ii) collective couplings. In both cases, we analytically show that the phenomenon of achieving PP compatibility, although reduced, it is still present. Searching for an optimisation of this phenomenon, we report numerical experiments up to n = 4 qubits. For individual qubit-noise coupling, be it a bit, a phase, or a bit–phase flip noise, the numerical search exhibits the same response to all the different noisy channels, without improving the analytical expectation. In contrast, the collective qubit-noise coupling leads to a more efficient numerical display of the phenomenon, and a variety of noise channel-dependent behaviours emerge. Furthermore, by adopting a slight modification of the definition of ψ-onticity, from being a property exclusively of sets of pure states to be a property of general sets of states (now ρ-onticity), in particular of the considered noisy set P, our results can also be seen as addressing the ρ-ontic realism of the set of n-qubit states P under the considered noisy channels.
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More From: Journal of Physics A: Mathematical and Theoretical
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