English

Imaging a large coronal loop using type U solar radio burst interferometry

Solar and Stellar Astrophysics 2024-02-08 v1

Abstract

Solar radio U-bursts are generated by electron beams traveling along closed magnetic loops in the solar corona. Low-frequency (<< 100 MHz) U-bursts serve as powerful diagnostic tools for studying large-sized coronal loops that extend into the middle corona. However, the positive frequency drift component (descending leg) of U-bursts has received less attention in previous studies, as the descending radio flux is weak. In this study, we utilized LOFAR interferometric solar imaging data from a U-burst that has a significant descending leg component, observed between 10 to 90 MHz on June 5th, 2020. By analyzing the radio source centroid positions, we determined the beam velocities and physical parameters of a large coronal magnetic loop that reached just about 1.3 R\rm{R_{\odot}} in altitude. At this altitude, we found the plasma temperature to be around 1.1 MK, the plasma pressure around 0.20 mdyn,cm2\rm{mdyn,cm^{-2}}, and the minimum magnetic field strength around 0.07 G. The similarity in physical properties determined from the image suggests a symmetric loop. The average electron beam velocity on the ascending leg was found to be 0.21 c, while it was 0.14 c on the descending leg. This apparent deceleration is attributed to a decrease in the range of electron energies that resonate with Langmuir waves, likely due to the positive background plasma density gradient along the downward loop leg.

Keywords

Cite

@article{arxiv.2402.04822,
  title  = {Imaging a large coronal loop using type U solar radio burst interferometry},
  author = {Jinge Zhang and Hamish A. S. Reid and Eoin Carley and Laurent Lamy and Pietro Zucca and Peijin Zhang and Baptiste Cecconi},
  journal= {arXiv preprint arXiv:2402.04822},
  year   = {2024}
}
R2 v1 2026-06-28T14:41:31.415Z