Imaging Spectroscopy of CME-Associated Solar Radio Bursts

TL;DR

This study uses imaging spectroscopy from OVRO-LWA to analyze a complex solar radio event associated with a CME, revealing a moving type IV burst and exploring its emission mechanism and physical conditions.

Contribution

First imaging spectroscopy analysis of a CME-associated solar radio burst at metric wavelengths, identifying a moving type IV source and constraining its emission mechanism and physical parameters.

Findings

Identified a moving type IV radio burst associated with CME core.

Estimated source velocity and correlated it with CME motion.

Suggested gyrosynchrotron emission as the plausible mechanism.

Abstract

We present first results of a solar radio event observed with the Owens Valley Radio Observatory Long Wavelength Array (OVRO-LWA) at metric wavelengths. We examine a complex event consisting of multiple radio sources/bursts associated with a fast coronal mass ejection (CME) and an M2.1 GOES soft X-ray flare from 2015 September 20. Images of 9--s cadence are used to analyze the event over a 120-minute period, and solar emission is observed out to a distance of $\approx3.5\,R_\odot$, with an instantaneous bandwidth covering 22~MHz within the frequency range of 40--70~MHz. We present our results from the investigation of the radio event, focusing particularly on one burst source that exhibits outward motion, which we classify as a moving type IV burst. We image the event at multiple frequencies and use the source centroids to obtain the velocity for the outward motion. Spatial and temporal comparison with observations of the CME in white light from the LASCO(C2) coronagraph, indicates an association of the outward motion with the core of the CME. By performing graduated-cylindrical-shell (GCS) reconstruction of the CME, we constrain the density in the volume. The electron plasma frequency obtained from the density estimates do not allow us to completely dismiss plasma emission as the underlying mechanism. However, based on source height and smoothness of the emission in frequency and time, we argue that gyrosynchrotron is the more plausible mechanism. We use gyrosynchrotron spectral fitting techniques to estimate the evolving physical conditions during the outward motion of this burst source.