A platform for investigating Bell correlations in pilot-wave hydrodynamics
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Since its discovery in 2005, the hydrodynamic pilot-wave system has provided a concrete macroscopic realization of wave-particle duality and concomitant classical analogs of a growing list of quantum effects. The question naturally arises as to whether this system might support statistical states that violate Bell's inequality, and so yield a classical analog of quantum entanglement. We here introduce a new platform for addressing this question, a numerical model of coupled bipartite tunneling in the hydrodynamic pilot-wave system. We demonstrate that, under certain conditions, the Bell inequality is violated in a static Bell test owing to correlations induced by the wave-mediated coupling between the two subsystems. The establishment of non-factorizable states with two spatially separated classical particles introduces the possibility of novel forms of quantum-inspired classical computing.
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Cited by 2 Pith papers
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Ontic Dynamical Locality Reduces to Bell Locality
Local dynamical hidden-variable models with ontological parameter independence are equivalent to static Bell models, so quantum correlations cannot arise from purely local dynamical complexity.
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Ontic Dynamical Locality Reduces to Bell Locality
Under ontic dynamical locality and measurement independence, all dynamical hidden-variable transition kernels reduce to effective static Bell-local response functions obeying CHSH.
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