High-resolution observational analysis of flare ribbon fine structures

TL;DR

This study provides the highest resolution observational evidence of fine-structure flare ribbons, revealing chromospheric bright blobs with specific sizes and periodicity, linked to magnetic reconnection processes during solar flares.

Contribution

It presents high-resolution spectroscopic observations of flare ribbon fine structures, supporting the connection between ribbon blobs and current sheet tearing in solar flares.

Findings

Detection of chromospheric bright blobs with 140-200 km width.

Blob periodicity of 330-550 km suggests fragmented reconnection.

Red wing asymmetry in intensity profiles indicates dynamic plasma processes.

Abstract

Context. Since the mechanism of energy release from solar flares is still not fully understood, the study of fine-scale features developing during flares becomes important for progressing towards a consistent picture of the essential physical mechanisms. Aims. We aim to probe the fine structures in flare ribbons at the chromospheric level using high-resolution observations with imaging and spectral techniques. Methods. We present a GOES C2.4 class solar flare observed with the Swedish 1-m Solar Telescope (SST), the Interface Region Imaging Spectrograph (IRIS), and the Atmospheric Imaging Assembly (AIA). The high-resolution SST observations offer spectroscopic data in the H-alpha, Ca II 8542 {\AA}, and H-beta lines, which we use to analyse the flare ribbon. Results. Within the eastern flare ribbon, chromospheric bright blobs were detected and analysed in Ca II 8542 {\AA}, H-alpha, and H-beta wavelengths. A comparison of blobs in H-beta observations and Si IV 1400 {\AA} has also been performed. These blobs are observed as almost circular structures having widths from 140 km-200 km. The intensity profiles of the blobs show a red wing asymmetry. Conclusions. From the high spatial and temporal resolution H-beta observations, we conclude that the periodicity of the blobs in the flare ribbon, which are near-equally spaced in the range 330-550 km, is likely due to fragmented reconnection processes within a flare current sheet. This supports the theory of a direct link between fine-structure flare ribbons and current sheet tearing. We believe our observations represent the highest resolution evidence of fine-structure flare ribbons to date.