Effect of interplanetary shock waves on turbulence parameters

TL;DR

This study analyzes how interplanetary shocks influence turbulence parameters in the solar wind, revealing dependencies on shock characteristics and implications for particle acceleration.

Contribution

It provides a comprehensive statistical analysis of turbulence parameter variations across interplanetary shocks at different distances from the Sun, including new insights into shock-related turbulence behaviors.

Findings

Antisunward imbalance and magnetic energy dominance are typical upstream properties.

Shock velocity jump and upstream beta influence turbulence parameter changes.

Occurrence of Alfvénic fluctuations decreases, while small-scale flux ropes increase downstream.

Abstract

We have performed an extensive statistical investigation of how interplanetary fast forward shocks affect certain turbulence parameters, namely, the cross-helicity, $\sigma_c$, residual energy, $\sigma_r$, and magnetic helicity, $\sigma_m$. A total of 371 shocks detected by Wind at 1 au and seven shocks by Solar Orbiter at 0.3-0.5 au have been analysed. We explore how the aforementioned turbulence parameters and their variation across the shock depend on shock characteristics including the gas compression ratio, upstream plasma beta, velocity jump and shock angle. In the shock vicinity, fluctuations tend on average to show antisunward imbalance (measured as $\sigma_c>0$ when rectified to the Parker spiral direction), a dominance of magnetic energy ($\sigma_r<0$) and zero $\sigma_m$, all being typical solar wind properties . Antisunward imbalance and equipartition ($\sigma_r \sim0$) in the upstream is increasingly prevalent with increasing shock velocity jump and decreasing upstream beta and shock angle. Shocks with large velocity jumps and gas compression ratios have considerably more balanced ($\sigma_c\sim0$) and more magnetically dominated fluctuations downstream than upstream. From upstream to downstream, we also find that the occurrence of time periods fulfilling strict criteria for Alfv\'enic fluctuations (AFs) usually decreases, while those meeting the criteria for small-scale flux ropes (SFRs) increases. The occurrence of AF periods peaks for quasi-parallel shocks with large velocity jumps and small upstream beta. The occurrence of SFRs increases with increasing gas compression ratio and upstream beta. The shocks observed by Solar Orbiter below 0.5 au display similar distributions of turbulence parameters and upstream-to-downstream changes to those detected at 1 au. These results are relevant for understanding turbulence and charged-particle acceleration at collisionless shocks.