Properties of a Small-scale Short-duration Solar Eruption with a Driven Shock

TL;DR

This study analyzes a small-scale, short-duration solar eruption with a driven shock, revealing unique kinematic features and energy relationships, and suggesting similarities between small- and large-scale solar eruptions.

Contribution

It provides detailed observations of a small-scale solar eruption with a driven shock, highlighting its rapid acceleration, shock formation, and energy distribution, which are rarely studied in such events.

Findings

Short acceleration phase (<2 min) with high acceleration (~50 km/s^2)

Formation of a low-height shock (<1.1 R_sun) within 2 minutes of acceleration

Similar magnetic energy consumption in small- and large-scale eruptions

Abstract

Large-scale solar eruptions have been extensively explored over many years. However, the properties of small-scale events with associated shocks have been rarely investigated. We present the analyses of a small-scale short-duration event originating from a small region. The impulsive phase of the M1.9-class flare lasted only for four minutes. The kinematic evolution of the CME hot channel reveals some exceptional characteristics including a very short duration of the main acceleration phase ($<$ 2 minutes), a rather high maximal acceleration rate ($\sim$50 km s$^{-2}$) and peak velocity ($\sim$1800 km s$^{-1}$). The fast and impulsive kinematics subsequently results in a piston-driven shock related to a metric type II radio burst with a high starting frequency of $\sim$320 MHz of the fundamental band. The type II source is formed at a low height of below $1.1~\mathrm{R_{\odot}}$ less than $\sim2$ minutes after the onset of the main acceleration phase. Through the band split of the type II burst, the shock compression ratio decreases from 2.2 to 1.3, and the magnetic field strength of the shock upstream region decreases from 13 to 0.5 Gauss at heights of 1.1 to 2.3 $~\mathrm{R_{\odot}}$. We find that the CME ($\sim4\times10^{30}\,\mathrm{erg}$) and flare ($\sim1.6\times10^{30}\,\mathrm{erg}$) consume similar amount of magnetic energy. The same conclusion for large-scale eruptions implies that small- and large-scale events possibly share the similar relationship between CMEs and flares. The kinematic particularities of this event are possibly related to the small footpoint-separation distance of the associated magnetic flux rope, as predicted by the Erupting Flux Rope model.