The quark-gluon plasma, turbulence, and quantum mechanics

TL;DR

This paper explores the hypothesis that quantum mechanics may emerge from turbulence in a relativistic fluid, using numerical analysis of a simplified cosmic fluid model to identify soliton-like solutions and chaotic behavior.

Contribution

It introduces a relativistic fluid model consistent with general relativity, demonstrating soliton solutions and chaotic dynamics that suggest a potential link to quantum mechanics.

Findings

Soliton-like solutions in the relativistic fluid model

Chaotic and stochastic behavior observed in simulations

Potential parallels between fluid turbulence and quantum phenomena

Abstract

Quark-gluon plasmas formed in heavy ion collisions at high energies are well described by ideal classical fluid equations with nearly zero viscosity. It is believed that a similar fluid permeated the entire universe at about three microseconds after the big bang. The estimated Reynolds number for this quark-gluon plasma at 3 microseconds is approximately 10^19. The possibility that quantum mechanics may be an emergent property of a turbulent proto-fluid is tentatively explored. A simple relativistic fluid equation which is consistent with general relativity and is based on a cosmic dust model is studied. A proper time transformation transforms it into an inviscid Burgers equation. This is analyzed numerically using a spectral method. Soliton-like solutions are demonstrated for this system, and these interact with the known ergodic behavior of the fluid to yield a stochastic and chaotic system which is time reversible. Various similarities to quantum mechanics are explored.