CME-Driven and Flare-Ignited Fast Magnetosonic Waves Successively Detected in a Solar Eruption

TL;DR

This study reports the detection of multiple fast magnetosonic waves during a solar eruption, revealing their origins from CME expansion and flare activity, and discusses their properties and implications for coronal seismology.

Contribution

First observation of successive fast magnetosonic waves driven by CME expansion and flare energy release in a single solar eruption event.

Findings

Large-scale EUV wave driven by CME expansion at 430 km/s.

Quasi-periodic EUV trains with periods of 110-120 seconds observed.

Waves provide insights into coronal seismology and energy transport.

Abstract

We present SDO/AIA observation of three types of fast-mode propagating magnetosonic waves in a GOES C3.0 flare on 2013 April 23, which was accompanied by a prominence eruption and a broad coronal mass ejection (CME). During the fast rising phase of the prominence, a large-scale dome-shaped extreme ultraviolet (EUV) wave firstly formed ahead of the CME bubble and propagated at a speed of about 430 km/s in the CME's lateral direction. One can identify the separation process of the EUV wave from the CME bubble. The reflection effect of the on-disk counterpart of this EUV wave was also observed when it interacted with a remote active region. Six minutes after the first appearance of the EUV wave, a large-scale quasi-periodic EUV train with a period of about 120 seconds appeared inside the CME bubble, which emanated from the flare epicenter and propagated outward at an average speed up to 1100 km/s. In addition, another narrow quasi-periodic EUV wave train was observed along a closed-loop system connecting two adjacent active regions, which also emanated from the flare epicenter, propagated at a speed of about475 km/s and with a period of about 110 seconds. We propose that all the observed waves are fast-mode magnetosonic waves, in which the large-scale dome-shaped EUV wave ahead of the CME bubble was driven by the expansion of the CME bubble, while the large-scale quasi-periodic EUV train within the CME bubble and the narrow quasi-periodic EUV wave train along the closed-loop system were excited by the intermittent energy-releasing process in the flare. Coronal seismology application and energy carried by the waves are also estimated based on the measured wave parameters.