Tracing magnetic switchbacks to their source: An assessment of solar coronal jets as switchback precursors

TL;DR

This study investigates whether small-scale coronal jets from bright points are precursors to magnetic switchbacks in the solar wind, using back-mapping, EUV imaging, and statistical analysis, but finds no definitive correlation.

Contribution

It provides a comprehensive analysis of the potential link between coronal jets and switchbacks, highlighting the complexities and limitations in establishing a direct connection.

Findings

Source region connectivity varies with source surface height.

Matching activity levels observed in some periods, but no direct correlation.

Limitations include modeling constraints and solar wind evolution effects.

Abstract

The origin of large-amplitude magnetic field deflections in the solar wind, known as magnetic switchbacks, is still under debate. These structures, which are ubiquitous in the observations made by Parker Solar Probe, likely have their seed in the lower solar corona, where small-scale events driven by magnetic reconnection could provide conditions ripe for either direct or indirect generation. We investigated potential links between in situ measurements of switchbacks and eruptions originating from the clusters of small-scale coronal loops known as coronal bright points to establish whether these eruptions act as precursors to switchbacks. We traced solar wind switchbacks from PSP back to their source regions using the ballistic back-mapping and potential field source surface methods, and analyzed the influence of the source surface height and solar wind propagation velocity on magnetic connectivity. Using EUV images, we combined automated and visual approaches to identify small-scale eruptions in the source regions. We find that the source region connected to the spacecraft varies significantly depending on the source surface height, which exceeds the expected dependence on the solar cycle and cannot be detected via polarity checks. For two corotation periods that are straightforwardly connected, we find a matching level of activity (jets and switchbacks), which is characterized by the hourly rate of events and depends on the size of the region connected to PSP. However, no correlation is found between the two time series of hourly event rates. Modeling constraints and the event selection may be the main limitations in the investigation of a possible correlation. Evolutionary phenomena occurring during the solar wind propagation may also influence our results. These results do not allow us to conclude that the jets are the main switchback precursors, nor do they rule out this hypothesis.