Capturing transient plasma flows and jets in the solar corona

TL;DR

This study uses high-cadence extreme-UV observations from Solar Orbiter to capture rapid plasma flows and jets in the solar corona, revealing dynamic magnetic reconnection signatures and jet evolution on 20-second timescales.

Contribution

First 2-second cadence UV observations of the solar corona capturing rapid magnetic reconnection signatures and jet activity, providing new insights into coronal plasma dynamics.

Findings

Localized heating events precede jet eruptions

Jets exhibit speeds of 100-150 km/s

Jet activity occurs on approximately 20 s timescales

Abstract

Intensity bursts in ultraviolet (UV) to X-ray wavelengths and plasma jets are typical signatures of magnetic reconnection and the associated impulsive heating of the solar atmospheric plasma. To gain new insights into the process, high-cadence observations are required to capture the rapid response of plasma to magnetic reconnection as well as the highly dynamic evolution of jets. Here, we report the first 2 s cadence extreme-UV observations recorded by the 174 {\AA} High Resolution Imager of the Extreme Ultraviolet Imager on board the Solar Orbiter mission. These observations, covering a quiet-Sun coronal region, reveal the onset signatures of magnetic reconnection as localized heating events. These localized sources then exhibit repeated plasma eruptions or jet activity. Our observations show that this spatial morphological change from localized sources to jet activity could occur rapidly on timescales of about 20 s. The jets themselves are intermittent and are produced from the source region on timescales of about 20 s. In the initial phases of these events, plasma jets are observed to exhibit speeds, as inferred from propagating intensity disturbances, in the range of 100 km s$^{-1}$ to 150 km s$^{-1}$. These jets then propagate to lengths of about 5 Mm. We discuss examples of bidirectional and unidirectional jet activity observed to have been initiated from the initially localized bursts in the corona. The transient nature of coronal bursts and the associated plasma flows or jets along with their dynamics could provide a benchmark for magnetic reconnection models of coronal bursts and jets.