0000000000243095

AUTHOR

Michał Hanasz

showing 7 related works from this author

Stability of hydrodynamical relativistic planar jets : II. Long-term nonlinear evolution

2004

In this paper we continue our study of the Kelvin-Helmholtz (KH) instability in relativistic planar jets following the long-term evolution of the numerical simulations which were introduced in Paper I. The models have been classified into four classes (I to IV) with regard to their evolution in the nonlinear phase, characterized by the process of jet/ambient mixing and momentum transfer. Models undergoing qualitatively different non-linear evolution are clearly grouped in well-separated regions in a jet Lorentz factor/jet-to-ambient enthalpy diagram. Jets with a low Lorentz factor and small enthalpy ratio are disrupted by a strong shock after saturation. Those with a large Lorentz factor an…

Lorentz transformationAstrophysics::High Energy Astrophysical PhenomenaFOS: Physical sciencesAstrophysicsUNESCO::ASTRONOMÍA Y ASTROFÍSICAAstrophysicsKinetic energyInstabilityMomentumsymbols.namesakeJetsMixing (physics)PhysicsJet (fluid)Momentum transferAstrophysics (astro-ph)Galaxies ; Jets ; Hydrodynamics ; InstabilitiesAstronomy and AstrophysicsMechanicsGalaxies:ASTRONOMÍA Y ASTROFÍSICA::Cosmología y cosmogonia [UNESCO]Lorentz factorSpace and Planetary ScienceInstabilitiessymbolsHydrodynamicsUNESCO::ASTRONOMÍA Y ASTROFÍSICA::Cosmología y cosmogonia:ASTRONOMÍA Y ASTROFÍSICA [UNESCO]
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Resonant Kelvin-Helmholtz modes in sheared relativistic flows

2007

Qualitatively new aspects of the (linear and non-linear) stability of sheared relativistic (slab) jets are analyzed. The linear problem has been solved for a wide range of jet models well inside the ultrarelativistic domain (flow Lorentz factors up to 20; specific internal energies $\approx 60c^2$). As a distinct feature of our work, we have combined the analytical linear approach with high-resolution relativistic hydrodynamical simulations, which has allowed us i) to identify, in the linear regime, resonant modes specific to the relativistic shear layer ii) to confirm the result of the linear analysis with numerical simulations and, iii) more interestingly, to follow the instability develo…

PhysicsJet (fluid)Field (physics)Lorentz transformationNumerical analysisAstrophysics::High Energy Astrophysical PhenomenaAstrophysics (astro-ph)FOS: Physical sciencesLinear regimePerturbation (astronomy)MechanicsAstrophysicsInstabilityLorentz factorNonlinear systemsymbols.namesakeClassical mechanicsAstrophysical jetQuantum mechanicsQuantum electrodynamicsHelmholtz free energysymbolsLinear growthBackground flow
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Influence of Internal Energy on the Stability of Relativistic Flows

2003

A set of simulations concerning the influence of internal energy on the stability of relativistic jets is presented. Results show that perturbations saturate when the amplitude of the velocity perturbation approaches the speed of light limit. Also, contrary to what predicted by linear stability theory, jets with higher specific internal energy appear to be more stable.

PhysicsShear layerClassical mechanicsAmplitudeInternal energyAstrophysical jetLinear stability theoryLinear stability analysisAstrophysics::High Energy Astrophysical PhenomenaPerturbation (astronomy)MechanicsAstrophysicsRelativistic particle
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Stability of three-dimensional relativistic jets: implications for jet collimation

2010

The stable propagation of jets in FRII sources is remarkable if one takes into account that large-scale jets are subjected to potentially highly disruptive three-dimensional (3D) Kelvin-Helmholtz instabilities. Numerical simulations can address this problem and help clarify the causes of this remarkable stability. Following previous studies of the stability of relativistic flows in two dimensions (2D), it is our aim to test and extend the conclusions of such works to three dimensions. We present numerical simulations for the study of the stability properties of 3D, sheared, relativistic flows. This work uses a fully parallelized code Ratpenat that solves equations of relativistic hydrodynam…

High Energy Astrophysical Phenomena (astro-ph.HE)PhysicsWork (thermodynamics)Jet (fluid)Astrophysics::High Energy Astrophysical PhenomenaFOS: Physical sciencesAstronomy and AstrophysicsContext (language use)MechanicsAstrophysicsStability (probability)GalaxyCollimated lightAstrophysical jetSpace and Planetary ScienceAstrophysics - High Energy Astrophysical PhenomenaShear flowAstronomy and Astrophysics
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Stability of hydrodynamical relativistic planar jets

2004

The effects of relativistic dynamics and thermodynamics in the development of Kelvin-Helmholtz instabilities in planar, relativistic jets along the early phases (namely linear and saturation phases) of evolution has been studied by a combination of linear stability analysis and high-resolution numerical simulations for the most unstable first reflection modes in the temporal approach. Three different values of the jet Lorentz factor (5, 10 and 20) and a few different values of specific internal energy of the jet matter (from 0.08 to $60.0 c^2$) have been considered. Figures illustrating the evolution of the perturbations are also shown.

FOS: Physical sciencesAstrophysicsUNESCO::ASTRONOMÍA Y ASTROFÍSICAAstrophysicssymbols.namesakeAstrophysical jetJetsPhysicsJet (fluid)Internal energyAstrophysics (astro-ph)Relativistic dynamicsAstronomy and AstrophysicsGalaxies:ASTRONOMÍA Y ASTROFÍSICA::Cosmología y cosmogonia [UNESCO]Lorentz factorSpace and Planetary ScienceQuantum electrodynamicsHelmholtz free energyHydrodynamicsReflection (physics)symbolsGalaxies ; Jets ; HydrodynamicsUNESCO::ASTRONOMÍA Y ASTROFÍSICA::Cosmología y cosmogonia[PHYS.ASTR] Physics [physics]/Astrophysics [astro-ph]Saturation (chemistry):ASTRONOMÍA Y ASTROFÍSICA [UNESCO]Astronomy & Astrophysics
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Nonlinear stability of relativistic sheared planar jets

2005

The linear and non-linear stability of sheared, relativistic planar jets is studied by means of linear stability analysis and numerical hydrodynamical simulations. Our results extend the previous Kelvin-Hemlholtz stability studies for relativistic, planar jets in the vortex sheet approximation performed by Perucho et al. (2004a,b) by including a shear layer between the jet and the external medium and more general perturbations. The models considered span a wide range of Lorentz factors ($2.5-20$) and internal energies ($0.08 c^2-60 c^2$) and are classified into three classes according to the main characteristics of their long-term, non-linear evolution. We observe a clear separation of thes…

PhysicsInternal energyLorentz transformationAstrophysics (astro-ph)FOS: Physical sciencesAstronomy and AstrophysicsMechanicsAstrophysicsGalaxies: jets ; Hydrodynamics ; InstabilitiesUNESCO::ASTRONOMÍA Y ASTROFÍSICAAstrophysicsKinetic energyWavelengthsymbols.namesakeLorentz factorAstrophysical jetMach numberSpace and Planetary ScienceInstabilitiesVortex sheetsymbolsHydrodynamicsjets [Galaxies]:ASTRONOMÍA Y ASTROFÍSICA [UNESCO]
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Stability of Relativistic Hydrodynamical Planar Jets: Linear and Nonlinear Evolution of Kelvin-Helmholtz Modes

2004

Some aspects about the stability of relativistic flows against Kelvin-Helmholtz (KH) perturbations are studied by means of relativistic, hydrodynamical simulations. In particular, we analyze the transition to the fully nonlinear regime and the long-term evolution of two jet models with different specific internal energies.

Physicssymbols.namesakeJet (fluid)Nonlinear systemClassical mechanicsPlanarAstrophysics::High Energy Astrophysical PhenomenaHelmholtz free energysymbolsNonlinear evolutionStability (probability)CosmologyRelativistic particle
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