Solar wind discontinuity transformation at the bow shock

TL;DR

This study investigates how solar wind rotational discontinuities interact with Earth's bow shock, revealing significant current density amplification influenced by magnetic compression, thinning, and wave interactions, with implications for magnetic reconnection and magnetospheric turbulence.

Contribution

It provides new insights into the mechanisms amplifying current density in RDs at the bow shock, highlighting the role of particle acceleration and wave interactions through combined observations and hybrid simulations.

Findings

Current density amplification can reach two orders of magnitude.

Magnetic compression and wave interactions are key factors.

Accelerated particles significantly boost reconnection likelihood.

Abstract

Solar wind plasma at the Earth's orbit carries transient magnetic field structures including discontinuities. Their interaction with the Earth's bow shock can significantly alter discontinuity configuration and stability. We investigate such an interaction for the most widespread type of solar wind discontinuities - rotational discontinuities (RDs). We use a set of in situ multispacecraft observations and perform kinetic hybrid simulations. We focus on the RD current density amplification that may lead to magnetic reconnection. We show that the amplification can be as high as two orders of magnitude and is mainly governed by three processes: the transverse magnetic field compression, global thinning of RD, and interaction of RD with low-frequency electromagnetic waves in the magnetosheath, downstream of the bow shock. The first factor is found to substantially exceed simple hydrodynamic predictions in most observed cases, the second effect has a rather moderate impact, while the third causes strong oscillations of the current density. We show that the presence of accelerated particles in the bow shock precursor highly boosts the current density amplification, making the postshock magnetic reconnection more probable. The pool of accelerated particles strongly affects the interaction of RDs with the Earth's bow shock, as it is demonstrated by observational data analysis and hybrid code simulations. Thus, shocks should be distinguished not by the inclination angle, but rather by the presence of foreshocks populated with shock reflected particles. Plasma processes in the RD-shock interaction affect magnetic structures and turbulence in the Earth's magnetosphere and may have implications for the processes in astrophysics.