Magnetic Field Intermittency in the Solar Wind: Parker Solar Probe and SolO Observations Ranging from the Alfven Region up to 1 AU

Parker Solar Probe (PSP) and SolO data are utilized to investigate magnetic field intermittency in the solar wind (SW). Small-scale intermittency (20-100 d ( i )) is observed to radially strengthen when methods relying on higher-order moments are considered (SF q ; SDK), but no clear trend is observed at larger scales. However, lower-order moment-based methods (e.g., partial variance of increments; PVI) are deemed more appropriate for examining the evolution of the bulk of coherent structures (CSs), PVI >= 3. Using PVI, we observe a scale-dependent evolution in the fraction of the data set occupied by CSs, f (PVI >= 3). Specifically, regardless of the SW speed, a subtle increase is found in f (PVI >= 3) for l = 20 d ( i ), in contrast to a more pronounced radial increase in CSs observed at larger scales. Intermittency is investigated in relation to plasma parameters. Though, slower SW speed intervals exhibit higher f (PVI >= 6) and higher kurtosis maxima, no statistical differences are observed for f (PVI >= 3). Highly Alfvenic intervals display lower levels of intermittency. The anisotropy with respect to the angle between the magnetic field and SW flow, Theta(VB) is investigated. Intermittency is weaker at Theta(VB) approximate to 0 degrees and is strengthened at larger angles. Considering the evolution at a constant alignment angle, a weakening of intermittency is observed with increasing advection time of the SW. Our results indicate that the strengthening of intermittency in the inner heliosphere is driven by the increase in comparatively highly intermittent perpendicular intervals sampled by the probes with increasing distance, an effect related directly to the evolution of the Parker spiral.

Automated summary

Parker Solar Probe and SolO data were used to investigate magnetic field intermittency in the solar wind. Small-scale intermittency was observed to strengthen radially, while no clear trend was observed at larger scales. Lower-order moment-based methods were considered more appropriate for examining the evolution of coherent structures. Intermittency was found to be related to plasma parameters and the angle between the magnetic field and solar wind flow.