6533b858fe1ef96bd12b63ad

RESEARCH PRODUCT

Linear theory of the Rayleigh–Taylor instability at a discontinuous surface of a relativistic flow

Miguel A. AloyManel PeruchoJin Matsumoto

subject

High Energy Astrophysical Phenomena (astro-ph.HE)PhysicsJet (fluid)OscillationAstrophysics::High Energy Astrophysical PhenomenaFOS: Physical sciencesAstronomy and AstrophysicsMechanics01 natural sciencesInstabilityAccelerationLorentz factorsymbols.namesakeSpace and Planetary Science0103 physical sciencessymbolsRayleigh–Taylor instabilityRestoring forceAstrophysics - High Energy Astrophysical Phenomena010306 general physics010303 astronomy & astrophysicsLinear stability

description

We address the linear stability of a discontinuous surface of a relativistic flow in the context of a jet that oscillates radially as it propagates. The restoring force of the oscillation is expected to drive a Rayleigh-Taylor instability (RTI) at the interface between the jet and its cocoon. We perform a linear analysis and numerical simulations of the growth of the RTI in the transverse plane to the jet flow with a uniform acceleration. In this system, an inertia force due to the uniform acceleration acts as the restoring force for the oscillation. We find that not only the difference in the inertia between the two fluids separated by the interface but also the pressure at the interface helps to drive the RTI because of a difference in the Lorenz factor across the discontinuous surface of the jet. The dispersion relation indicates that the linear growth rate of each mode becomes maximum when the Lorentz factor of the jet is much larger than that of the cocoon and the pressure at the jet interface is relativistic. By comparing the linear growth rates of the RTI in the analytical model and the numerical simulations, the validity of our analytically derived dispersion relation for the relativistic RTI is confirmed.

yearjournalcountryeditionlanguage
2017-07-15Monthly Notices of the Royal Astronomical Society
https://doi.org/10.1093/mnras/stx2012