Small-Scale Structuring Of Ellerman Bombs at Solar Limb

TL;DR

This study investigates the vertical structuring and dynamics of Ellerman bombs at the solar limb, revealing their parabolic motion and potential links to small-scale magnetic flux emergence, expanding understanding of their role in the solar atmosphere.

Contribution

The paper provides high-resolution observations of EBs at the solar limb, demonstrating their vertical motions and association with small-scale magnetic phenomena, which was not previously well documented.

Findings

Most EBs follow a parabolic path with an average speed of 9 km/s.

Ebs extend approximately 580 km away from their source before retreating.

Ebs are linked to small-scale flux emergence and other explosive events.

Abstract

Ellerman bombs (EBs) have been widely studied in recent years due to their dynamic, explosive nature and apparent links to the underlying photospheric magnetic field implying that they may be formed by magnetic reconnection in the photosphere. Despite a plethora of researches discussing the morphologies of EBs, there has been a limited investigation of how these events appear at the limb, specifically, whether they manifest as vertical extensions away from the disc. In this article, we make use of high-resolution, high-cadence observations of an AR at the solar limb, collected by the CRISP instrument, to identify EBs and infer their physical properties. The upper atmosphere is also probed using the SDO/AIA. We analyse 22 EB events evident within these data, finding that 20 appear to follow a parabolic path away from the solar surface at an average speed of 9 km s^(-1), extending away from their source by 580 km, before retreating back at a similar speed. These results show strong evidence of vertical motions associated with EBs, possibly explaining the dynamical `flaring' (changing in area and intensity) observed in on-disc events. Two in-depth case studies are also presented which highlight the unique dynamical nature of EBs within the lower solar atmosphere. The viewing angle of these observations allows for a direct linkage between these EBs and other small-scale events in the H-alpha line wings, including a potential flux emergence scenario. The findings presented here suggest that EBs could have a wider-reaching influence on the solar atmosphere than previously thought, as we reveal a direct linkage between EBs and an emerging small-scale loop, and other near-by small-scale explosive events. However, as previous research found, these extensions do not appear to impact upon the H-alpha line core, and are not observed by the SDO/AIA EUV filters.