A realistic interpretation of quantum wavefunctions as temperature dependent vacuum polarization waves

We discuss in this paper a novel interpretation of Born rule as an approxi-mated thermodynamic law which emerges from the interaction of a quantumsystem with a non-stationary thermal bath associated to vacuum fluctuationsinduced by external environment radiation. In particular we assume thatvacuum polarization is a real non relativistic phenomena caused by hiddenvacuum charge oscillations which diffuses heat energy in a dispersive and dis-sipative dielectric medium with a temperature dependent speed of propaga-tion. We propose a model which couples vacuum wavefunctions to vacuumcharge fluctuations and we deduce a temperature dependent running finestructure constant function proportional, at first approximation, to thesquared of the effective electron charge and compatible with known experi-mental data. We interpret the vacuum symmetry breaking energy fluctuationsinduced in scattering experiments of particle physics and in laser assisted nu-clear reactions as thermal quasi-monochromatic beams produced by the de-cay of hidden non equilibrium massive photons propagating with a variablelight speed. We suggest, exploiting an old analogy between plasmons andpseudo Goldstone bosons, to interpret heat diffusion of this non relativisticpolarized vacuum as a real De Broglie electromagnetic scalar wave associatedto the radiation emitted by the hidden massive photons with accelerationproportional to vacuum Unruh like temperature. We predict a temperaturedependent deviation from Coulomb law and a generalized dispersive law ofthese hidden unstable photons that could be revealed as not stationary col-oured noise in experiments on anomalous heat diffusions associated to thedecay of unstable accelerated pairs produced in nuclear physics experiments.We discuss then how our proposal of a temperature dependent non relativis-tic vacuum polarization might be applied to deduce a dynamic generalizationof Born rule based on a realistic interpretation of quantum wavefunctions as averaged electromagnetic waves of hidden massive photons. Finally we sug-gest to test our time asymmetric model looking for very fast oscillating po-larization thermal waves emitted during the not instantaneous wavefunctioncollapse and revealed as not stationary bulk heating effects in experiments onaccelerated conductors and nanoconductors