Large-amplitude longitudinal oscillations in solar prominences simulated with different resolutions

TL;DR

This study uses high-resolution numerical simulations to investigate the damping and amplification mechanisms of large-amplitude longitudinal oscillations in solar prominences, revealing the importance of resolution in capturing physical processes.

Contribution

It demonstrates that high spatial resolution is essential to accurately model LALOs, showing how damping and amplification depend on physical effects rather than numerical artifacts.

Findings

Period matches pendulum model at high resolution

Damping time saturates with increasing resolution

Oscillations are amplified at prominence top initially

Abstract

Large-amplitude longitudinal oscillations (LALOs) in solar prominences have been widely studied in the last decades. However, their damping and amplification mechanisms are not well understood. In this study, we investigate the attenuation and amplification of LALOs using high-resolution numerical simulations with progressively increasing spatial resolutions. We performed time-dependent numerical simulations of LALOs using the 2D magnetic configuration that contains a dipped region. After the prominence mass loading in the magnetic dips, we triggered LALOs by perturbing the prominence mass along the magnetic field. We performed the experiments with four values of spatial resolution. In the simulations with the highest resolution, the period shows a good agreement with the pendulum model. The convergence experiment revealed that the damping time saturates at the bottom prominence region with improving the resolution, indicating the existence of a physical reason for the damping of oscillations. At the prominence top, the oscillations are amplified during the first minutes and then are slowly attenuated. The characteristic time suggests more significant amplification in the experiments with the highest spatial resolution. The analysis revealed that the energy exchange between the bottom and top prominence regions is responsible for the attenuation and amplification of LALOs. The high-resolution experiments are crucial for the study of the periods and the damping mechanism of LALOs. The period agrees with the pendulum model only when using high enough spatial resolution. The results suggest that numerical diffusion in simulations with insufficient spatial resolution can hide important physical mechanisms, such as amplification of oscillations.