A tiny event producing an interplanetary type III burst

TL;DR

This study shows that small-scale energy releases in the solar corona can generate significant interplanetary type III radio bursts, especially when occurring near open magnetic field regions, revealing details of electron acceleration and propagation.

Contribution

It provides detailed multi-instrument analysis of tiny solar events producing interplanetary type III bursts, highlighting the role of magnetic topology and energy release location.

Findings

Tiny energy releases can produce powerful IP type III bursts.

Events near coronal hole boundaries are more likely to generate IP type IIIs.

Electron beams can escape along open magnetic field lines from small flaring loops.

Abstract

We investigate the conditions under which small scale energy release events in the low corona gave rise to strong interplanetary (IP) type III bursts. We analyze observations of three tiny events, detected by the Nan\c cay Radio Heliograph (NRH), two of which produced IP type IIIs. We took advantage of the NRH positioning information and of the high cadence of AIA/SDO data to identify the associated EUV emissions. We measured positions and time profiles of the metric and EUV sources. We found that the EUV events that produced IP type IIIs were located near a coronal hole boundary, while the one that did not was located in a closed magnetic field region. In all three cases tiny flaring loops were involved, without any associated mass eruption. In the best observed case the radio emission at the highest frequency (435 MHz) was displaced by ~55" with respect to the small flaring loop. The metric type III emission shows a complex structure in space and in time, indicative of multiple electron beams, despite the low intensity of the events. From the combined analysis of dynamic spectra and NRH images we derived the electron beam velocity as well as the height, ambient plasma temperature and density at the level of formation of the 160 MHz emission. From the analysis of the differential emission measure derived from the AIA images we found that the first evidence of energy release was at the footpoints and this was followed by the development of flaring loops and subsequent cooling. We conclude that even small energy release events can accelerate enough electrons to give rise to powerful IP type III bursts. The proximity of the electron acceleration site to open magnetic field lines facilitates the escape of the electrons into the interplanetary space. The offset between the site of energy release and the metric type III location warrants further investigation.