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First order non-Lorentzian fluids, entropy production, and linear instabilities

Napat Poovuttikul, Watse Sybesma

2020Physical review. D/Physical review. D.31 citationsDOIOpen Access PDF

Abstract

In this paper, we investigate linear instabilities of hydrodynamics with corrections up to first order in derivatives. It has long been known that relativistic (Lorentzian) first order hydrodynamics, with positive local entropy production, exhibits unphysical instabilities. We extend this analysis to fluids with Galilean and Carrollian boost symmetries. We find that the instabilities occur in all cases, except for fluids with Galilean boost symmetry combined with the choice of macroscopic variables called Eckart frame. We also present a complete linearized analysis of the full spectrum of first order Carrollian hydrodynamics. Furthermore, we show that even in a fluid without boost symmetry present, instabilities can occur. These results provide evidence that the unphysical instabilities are symptoms of first order hydrodynamics, rather than a special feature of Lorentzian fluids.

Topics & Concepts

GalileanPhysicsEntropy productionHomogeneous spaceSymmetry (geometry)Classical mechanicsEntropy (arrow of time)Nonlinear systemFirst orderTheoretical physicsStatistical physicsQuantum mechanicsMathematicsGeometryApplied mathematicsFluid Dynamics and Turbulent FlowsCosmology and Gravitation TheoriesBlack Holes and Theoretical Physics
First order non-Lorentzian fluids, entropy production, and linear instabilities | Litcius