Wave heating in simulated multi-stranded coronal loops
Abstract
It has been found that the Kelvin-Helmholtz instability (KHI) induced by both transverse and torsional oscillations in coronal loops can reinforce the effects of wave heating. In this study, we model a coronal loop as a system of individual strands, and we study wave heating effects by considering a combined transverse and torsional driver at the loop footpoint. We deposit the same energy into the multi-stranded loop and an equivalent monolithic loop, and then observe a faster increase in the internal energy and temperature in the multi-stranded model. Therefore, the multi-stranded model is more efficient in starting the heating process. Moreover, higher temperature is observed near the footpoint in the multi-stranded loop and near the apex in the monolithic loop. The apparent heating location in the multi-stranded loop agrees with the previous predictions and observations. Given the differences in the results from our multi-stranded loop and monolithic loop simulations, and given that coronal loops are suggested to be multi-stranded on both theoretical and observational grounds, our results suggest that the multi-strandedness of coronal loops needs to be incorporated in future wave-based heating mechanisms.
Keywords
Cite
@article{arxiv.1907.08013,
title = {Wave heating in simulated multi-stranded coronal loops},
author = {Mingzhe Guo and Tom Van Doorsselaere and Konstantinos Karampelas and Bo Li},
journal= {arXiv preprint arXiv:1907.08013},
year = {2019}
}
Comments
8 figures, accepted for publication in ApJ