Shock-related radio emission during coronal mass ejection lift-off?

TL;DR

This study investigates the origin of fast-drifting radio emissions associated with CMEs, proposing super-Alfvenic loop expansion as the shock driver, challenging traditional models linking shocks to CME flanks or flare blast waves.

Contribution

The paper provides evidence that super-Alfvenic loop expansion, rather than CME flanks or flare blast waves, initiates coronal shocks observed as fast-drifting radio emissions.

Findings

Fast-drift radio bursts correspond to propagating shock fronts.

Super-Alfvenic loop expansion likely drives the shock wave.

CME bow shocks are unlikely sources of the observed radio emissions.

Abstract

Aims: We identify the source of fast-drifting decimetric-metric radio emission that is sometimes observed prior to the so-called flare continuum emission. Fast-drift structures and continuum bursts are also observed in association with coronal mass ejections (CMEs), not only flares. Methods: We analyse radio spectral features and images acquired at radio, H-alpha, EUV, and soft X-ray wavelengths, during an event close to the solar limb on 2 June 2003. Results: The fast-drifting decimetric-metric radio burst corresponds to a moving, wide emission front in the radio images, which is normally interpreted as a signature of a propagating shock wave. A decimetric-metric type II burst where only the second harmonic lane is visible could explain the observations. After long-lasting activity in the active region, the hot and dense loops could be absorbing or suppressing emission at the fundamental plasma frequency. The observed burst speed suggests a super-Alfvenic velocity for the burst driver. The expanding and opening loops, associated with the flare and the early phase of CME lift-off, could be driving the shock. Alternatively, an instantaneous but fast loop expansion could initiate a freely propagating shock wave. The later, complex-looking decametre-hectometre wave type III bursts indicate the existence of a propagating shock, although no interplanetary type II burst was observed during the event. The data does not support CME bow shock or a shock at the flanks of the CME as the origin of the fast-drift decimetric-metric radio source. Therefore super-Alfvenic loop expansion is the best candidate for the initiation of the shock wave, and this result challenges the current view of metric/coronal shocks originating either in the flanks of CMEs or from flare blast waves.