On the properties of Alfvenic switchbacks in the expanding solar wind: The influence of the Parker spiral

Switchbacks-rapid, large deflections of the solar wind's magnetic field-have generated interest as possible signatures of the mechanisms that heat the corona and accelerate the solar wind. In this context, an important task for theories of switchback formation and evolution is to understand their observable distinguishing features, allowing them to be carefully assessed using spacecraft data. Here, we work toward this goal by studying how Alfvenic switchbacks evolve in the expanding solar wind beyond the Alfven radius, when the background magnetic field also rotates due to the Parker spiral. Using simple analytic arguments based on the physics of one-dimensional spherically polarized (constant-field-magnitude) Alfven waves, we find that, by controlling the wave's obliquity, a Parker spiral strongly impacts switchback properties. Surprisingly, parallel magnetic-field deflections (switchbacks) can grow faster in a Parker spiral than in a radial background field, even though normalized wave amplitudes grow more slowly. In addition, switchbacks become strongly asymmetric: large switchbacks preferentially involve magnetic-field rotations in the plane of the Parker spiral (tangential deflections) rather than perpendicular (normal) rotations, and such deflections are strongly tangentially skewed, meaning switchbacks always involve field rotations in the same direction (toward the positive-radial direction for an outward mean field). In a companion paper [Johnston et al., Phys. Plasmas 29, 072902 1346 (2022)], we show that these properties also occur in turbulent 3D fields with switchbacks, given various caveats. Given that these nontrivial asymmetries and correlations develop purely as a consequence of switchback propagation in the solar wind, our results show that in situ observed asymmetrical switchback features cannot be used straightforwardly to infer properties of sources in the low corona. Published under an exclusive license by AIP Publishing.

Automated summary

This study investigates the evolution of Alfvenic switchbacks in the expanding solar wind beyond the Alfven radius, considering the rotation of the background magnetic field due to the Parker spiral. The results show that the Parker spiral strongly impacts switchback properties, leading to asymmetries and preferential rotations in a specific direction. These findings indicate that observed asymmetrical switchback features cannot be used straightforwardly to infer properties of sources in the low corona.