Interferometric imaging, and beam-formed study of a moving Type IV Radio burst with LOFAR

TL;DR

This study uses LOFAR interferometric imaging to analyze a moving Type IV radio burst, revealing fine structures, polarization evolution, and kinematics, providing insights into emission mechanisms like gyrosynchrotron and ECM.

Contribution

First high-resolution LOFAR imaging of a moving Type IV burst, combining radio and white light data to analyze fine structures, polarization, and source motion.

Findings

DCP increased from 10% to 20% during the event

Detected numerous fine structures with sub-second duration

Observed westward motion slower than CME leading edge

Abstract

Type IV radio burst has been studied for over 50 years. However, the specifics of the radio emission mechanisms is still an open question. In order to provide more information about the emission mechanisms, we studied a moving type IV radio burst with fine structures (spike group) by using the high resolution capability of Low-Frequency Array (LOFAR) on Aug 25, 2014\textbf{ (SOLA-D-21-00188)}. We present a comparison of Nan\c{c}ay RadioHeliograph (NRH) and the first LOFAR imaging data of type IV radio burst. The degree of circular polarization (DCP) is calculated at frequencies in the range 20$\sim$180 MHz using LOFAR data, and it was found that the value of DCP gradually increased during the event, with values of 10\%$\sim$20\%. LOFAR interferometric data were combined with white light observations in order to track the propagation of this type IV. The kinematics shows a westward motion of the radio sources, slower than the CME leading edge. The dynamic spectrum of LOFAR shows a large number of fine structures with duration of less than 1s and high brightness temperature ($T_\mathrm{B}$), i.e. $10^{12}$$\sim$$10^{13}$ K. The gradual increase of DCP supports gyrosynchrotron emission as the most plausible mechanism for the type IV. However, coherent emissions such as Electron Cyclotron Maser (ECM) instability can be responsible for small scale fine structures. Countless fine structures altogether were responsible for such high $T_\mathrm{B}$.