Microwave imaging of a hot flux rope structure during the pre-impulsive stage of an eruptive M7.7 solar flare

TL;DR

This study uses microwave imaging to reveal the structure and dynamics of a hot flux rope during the early stage of a solar flare, providing insights into magnetic configurations and reconnection processes.

Contribution

First microwave imaging analysis of a hot flux rope during the pre-impulsive stage of an eruptive solar flare, linking microwave emissions to magnetic and reconnection processes.

Findings

Flux rope appears as an arcade-like microwave structure with intensity enhancements.

Microwave brightness temperatures range from ~10,000 K to ~20,000 K.

A 2-minute periodicity in microwave emission suggests intermittent reconnection.

Abstract

Corona structures and processes during the pre-impulsive stage of solar eruption are crucial to understanding the physics leading to the subsequent explosive energy release. Here we present the first microwave imaging study of a hot flux rope structure during the pre-impulsive stage of an eruptive M7.7 solar flare, with the Nobeyama Radioheliograph (NoRH) at 17 GHz. The flux rope is also observed by the SDO/AIA in its hot passbands of 94 and 131 \AA\. In the microwave data, it is revealed as an overall arcade-like structure consisting of several intensity enhancements bridged by generally weak emissions, with brightness temperatures ($T_B$) varying from ~10,000~K to ~20,000 K. Locations of microwave intensity enhancements along the structure remain relatively fixed at certain specific parts of the flux rope, indicating that the distribution of emitting electrons is affected by the large scale magnetic configuration of the twisted flux rope. Wavelet analysis shows a pronounced 2-min period of the microwave $T_B$ variation during the pre-impulsive stage of interest. The period agrees well with that reported for AIA sunward-contracting loops and upward ejective plasmoids (suggested to be reconnection outflows). This suggests that both periodicities are controlled by the same reconnection process that takes place intermittently at a 2-min time scale. We infer that at least a part of the emission is excited by non-thermal energetic electrons via the gyro-synchrotron mechanism. The study demonstrates the potential of microwave imaging in exploring the flux rope magnetic geometry and relevant reconnection process during the onset of solar eruption.