Iris si iv line profiles: An indication for the plasmoid instability during small-scale magnetic reconnection on the sun

TL;DR

This study uses IRIS spectroscopic data to analyze small-scale solar reconnection events, finding that plasmoid instability, rather than Petschek reconnection, likely explains the observed line profiles and fast reconnection processes.

Contribution

It provides observational evidence supporting plasmoid instability as the mechanism for fast magnetic reconnection in small-scale solar events.

Findings

Line profiles show complex structures with bright cores and broad wings.

Profiles are consistent with plasmoid instability, not Petschek mechanism.

Reconnection proceeds via plasmoid instability during small-scale solar events.

Abstract

Our understanding of the process of fast reconnection has undergone a dramatic change in the last 10 years driven, in part, by the availability of high-resolution numerical simulations that have consistently demonstrated the break-up of current sheets into magnetic islands, with reconnection rates that become independent of Lundquist number, challenging the belief that fast magnetic reconnection in flares proceeds via the Petschek mechanism that invokes pairs of slow-mode shocks connected to a compact diffusion region. The reconnection sites are too small to be resolved with images but these reconnection mechanisms, Petschek and the plasmoid instability, have reconnection sites with very different density and velocity structures and so can be distinguished by high-resolution line-profiles observations. Using IRIS spectroscopic observations we obtain a survey of typical line profiles produced by small-scale events thought to be reconnection sites on the Sun. Slit-jaw images are used to investigate the plasma heating and re-configuration at the sites. A sample of 15 events from two active regions is presented. The line profiles are complex with bright cores and broad wings extending to over 300 km/s. The profiles can be reproduced with the multiple magnetic islands and acceleration sites that characterise the plasmoid instability but not by bi-directional jets that characterise the Petschek mechanism. This result suggests that if these small-scale events are reconnection sites, then fast reconnection proceeds via the plasmoid instability, rather than the Petschek mechanism during small-scale reconnection on the Sun.