Energy transport during 3D small-scale reconnection driven by anisotropic plasma turbulence

TL;DR

This paper investigates energy transport and dissipation during 3D small-scale magnetic reconnection in anisotropic plasma turbulence using kinetic simulations, revealing electron flow's role and plasma compression dominance.

Contribution

It provides new insights into energy transfer mechanisms in turbulent reconnection, highlighting the importance of plasma compression and electron bulk flow in energy dissipation.

Findings

Electron bulk flow efficiently transports thermal energy.

Energy transfer is dominated by plasma compression.

Reconnection involves asymmetric flux ropes in turbulence.

Abstract

Energy dissipation in collisionless plasmas is a longstanding fundamental physics problem. Although it is well known that magnetic reconnection and turbulence are coupled and transport energy from system-size scales to sub-proton scales, the details of the energy distribution and energy dissipation channels remain poorly understood. Especially, the energy transfer and transport associated with three dimensional (3D) small-scale reconnection that occurs as a consequence of a turbulent cascade is unknown. We use an explicit fully kinetic particle-in-cell code to simulate 3D small scale magnetic reconnection events forming in anisotropic and Alfv\'enic decaying turbulence. We identify a highly dynamic and asymmetric reconnection event that involves two reconnecting flux ropes. We use a two-fluid approach based on the Boltzmann equation to study the spatial energy transfer associated with the reconnection event and compare the power density terms in the two-fluid energy equations with standard energy-based damping, heating and dissipation proxies. Our findings suggest that the electron bulk flow transports thermal energy density more efficiently than kinetic energy density. Moreover, in our turbulent reconnection event, the energy-density transfer is dominated by plasma compression. This is consistent with turbulent current sheets and turbulent reconnection events, but not with laminar reconnection.