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Nonlinear Damping of Standing Kink Waves Computed With Elsässer Variables

Tom Van Doorsselaere, Marcel Goossens, Norbert Magyar, Michael S. Ruderman, Rajab Ismayilli

2021The Astrophysical Journal34 citationsDOIOpen Access PDF

Abstract

Abstract In a previous paper, we computed the energy density and the nonlinear energy cascade rate for transverse kink waves using Elsässer variables. In this paper, we focus on the standing kink waves, which are impulsively excited in coronal loops by external perturbations. We present an analytical calculation to compute the damping time due to the nonlinear development of the Kelvin–Helmholtz instability. The main result is that the damping time is inversely proportional to the oscillation amplitude. We compare the damping times from our formula with the results of numerical simulations and observations. In both cases we find a reasonably good match. The comparison with the simulations shows that the nonlinear damping dominates in the high amplitude regime, while the low amplitude regime shows damping by resonant absorption. In the comparison with the observations, we find a power law inversely proportional to the amplitude η −1 as an outer envelope for our Monte Carlo data points.

Topics & Concepts

PhysicsAmplitudeOscillation (cell signaling)Nonlinear systemMagnetic dampingEnvelope (radar)Transverse planeCascadeMonte Carlo methodQuantum electrodynamicsExcited stateClassical mechanicsMechanicsEnergy (signal processing)Energy cascadeLandau dampingHarmonicsComputational physicsPower lawStanding waveNumerical analysisNonlinear OscillationsComputer simulationSolar and Space Plasma DynamicsIonosphere and magnetosphere dynamicsNonlinear Waves and Solitons
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