IRIS observations of the low-atmosphere counterparts of active region outflows

TL;DR

This study uses IRIS observations to analyze the low-atmosphere counterparts of active region outflows, revealing complex spectral features and dynamic links between the chromosphere, transition region, and corona, challenging existing models.

Contribution

It provides new insights into the low-atmosphere dynamics associated with AR outflows, emphasizing the importance of the chromosphere and transition region in understanding these phenomena.

Findings

IRIS spectral lines show different features in outflows compared to moss and quiet Sun.

Coronal outflows are linked with chromospheric upflows and TR signatures.

Low atmosphere underneath outflows is highly structured with blueshifts and asymmetries.

Abstract

Active region (AR) outflows have been studied in detail since the launch of \textit{Hinode}/EIS and are believed to provide a possible source of mass and energy to the slow solar wind. In this work, we investigate the lower atmospheric counterpart of AR outflows using observations from the \textit{Interface Region Imaging Spectrograph} (\textit{IRIS}). We find that the \textit{IRIS} \siiv, \cii\ and \mgii\ transition region (TR) and chromospheric lines exhibit different spectral features in the outflows as compared to neighboring regions at the footpoints ("moss") of hot AR loops. The average redshift of \siiv\ in the outflows region ($\approx$ 5.5~km s$^{-1}$) is smaller than typical moss ($\approx$ 12--13 km~s$^{-1}$) and quiet Sun ($\approx$ 7.5 km~s$^{-1}$) values, while the \cii~line is blueshifted ($\approx$ -1.1--1.5 km~s$^{-1}$), in contrast to the moss where it is observed to be redshifted by about $\approx$ 2.5 km~s$^{-1}$. Further, we observe that the low atmosphere underneath the coronal outflows is highly structured, with the presence of blueshifts in \siiv\ and positive \mgii\ k2 asymmetries (which can be interpreted as signatures of chromospheric upflows) which are mostly not observed in the moss. These observations show a clear correlation between the coronal outflows and the chromosphere and TR underneath, which has not been shown before. Our work strongly suggests that these regions are not separate environments and should be treated together, and that current leading theories of AR outflows, such as the interchange reconnection model, need to take into account the dynamics of the low atmosphere.