Litcius/Paper detail

General-relativistic hydrodynamics of non-perfect fluids: 3+1 conservative formulation and application to viscous black hole accretion

Michail Chabanov, Luciano Rezzolla, Dirk H. Rischke

2021Monthly Notices of the Royal Astronomical Society45 citationsDOIOpen Access PDF

Abstract

ABSTRACT We consider the relativistic hydrodynamics of non-perfect fluids with the goal of determining a formulation that is suited for numerical integration in special-relativistic and general-relativistic scenarios. To this end, we review the various formulations of relativistic second-order dissipative hydrodynamics proposed so far and present in detail a particular formulation that is fully general, causal, and can be cast into a 3+1 flux-conservative form, as the one employed in modern numerical-relativity codes. As an example, we employ a variant of this formulation restricted to a relaxation-type equation for the bulk viscosity in the general-relativistic magnetohydrodynamics code bhac. After adopting the formulation for a series of standard and non-standard tests in 1+1-dimensional special-relativistic hydrodynamics, we consider a novel general-relativistic scenario, namely, the stationary, spherically symmetric, viscous accretion on to a black hole. The newly developed solution – which can exhibit even considerable deviations from the inviscid counterpart – can be used as a testbed for numerical codes simulating non-perfect fluids on curved backgrounds.

Topics & Concepts

PhysicsInviscid flowClassical mechanicsDissipative systemAstrophysical jetGeneral relativityNumerical relativityAccretion (finance)Black hole (networking)Relativistic speedRelativistic quantum chemistryRotating black holeMechanicsRelativistic particleActive galactic nucleusAstrophysicsRouting protocolGalaxyQuantum mechanicsNuclear physicsLink-state routing protocolRouting (electronic design automation)ElectronComputer networkComputer sciencePulsars and Gravitational Waves ResearchAstrophysical Phenomena and ObservationsBlack Holes and Theoretical Physics