Characteristics of Interplanetary Discontinuities in the Inner Heliosphere Revealed by Parker Solar Probe

TL;DR

This study analyzes interplanetary discontinuities in the solar wind from 0.13 to 0.9 au using Parker Solar Probe data, revealing their spatial distribution, evolution, and physical properties to better understand solar wind turbulence.

Contribution

It provides the first comprehensive statistical analysis of ID characteristics and their evolution in the inner heliosphere based on Parker Solar Probe measurements.

Findings

ID occurrence rate decreases with distance following r-2.00

RD to TD ratio drops from 8 to 1 between 0.3 and 0.4 au

Normalized RD thicknesses follow r-1.09 scaling

Abstract

We present a statistical analysis for the characteristics and spatial evolution of the interplanetary discontinuities (IDs) in the solar wind, from 0.13 to 0.9 au, by using the Parker Solar Probe measurements on Orbits 4 and 5. 3948 IDs have been collected, including 2511 rotational discontinuities (RDs) and 557 tangential discontinuities (TDs), with the remnant unidentified. The statistical results show that (1) the ID occurrence rate decreases from 200 events/day at 0.13 au to 1 events/day at 0.9 au, following a spatial scaling r-2.00, (2) the RD to TD ratio decreases quickly with the heliocentric distance, from 8 at r<0.3 au to 1 at r>0.4 au, (3) the magnetic field tends to rotate across the IDs, 45{\deg} for TDs and 30{\deg} for RDs in the pristine solar wind within 0.3 au, (4) a special subgroup of RDs exist within 0.3 au, characterized by small field rotation angles and parallel or antiparallel propagations to the background magnetic fields, (5) the TD thicknesses normalized by local ion inertial lengths (di) show no clear spatial scaling and generally range from 5 to 35 di, and the normalized RD thicknesses follow r-1.09 spatial scaling, (6) the outward (anti-sunward) propagating RDs predominate in all RDs, with the propagation speeds in the plasma rest frame proportional to r-1.03. This work could improve our understandings for the ID characteristics and evolutions and shed light on the study of the turbulent environment in the pristine solar wind.