P. Fernandez de Cordoba, J. M. Isidro, J. Vazquez Molina
Published 2014-09-24Version 1
Quantum mechanics has been argued to be a coarse-graining of some underlying deterministic theory. Here we support this view by establishing a map between certain solutions of the Schroedinger equation, and the corresponding solutions of the irrotational Navier-Stokes equation for viscous fluid flow. As a physical model for the fluid itself we propose the quantum probability fluid. It turns out that the (state-dependent) viscosity of this fluid is proportional to Planck's constant, while the volume density of entropy is proportional to Boltzmann's constant. Stationary states have zero viscosity and a vanishing time rate of entropy density. On the other hand, the nonzero viscosity of nonstationary states provides an information-loss mechanism whereby a deterministic theory (a classical fluid governed by the Navier-Stokes equation) gives rise to an emergent theory (a quantum particle governed by the Schroedinger equation).
Quasiseparation of variables in the Schroedinger equation with a magnetic field
Diophantine approximation and the solubility of the Schroedinger equation
Diffusion for a quantum particle coupled to phonons in $d\geq 3$
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