Topology of turbulence within collisionless plasma reconnection
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https://hdl.handle.net/10037/31932Date
2023-10-31Type
Journal articleTidsskriftartikkel
Peer reviewed
Abstract
In near-collisionless plasmas, which are ubiquitous in astrophysics, entropy production relies on
fully-nonlinear processes such as turbulence and reconnection, which lead to particle acceleration.
Mechanisms for turbulent reconnection include multiple magnetic fux ropes interacting to generate
thin current sheets which undergo reconnection, leading to mixing and magnetic merging and growth
of coherent structures, unstable reconnection current layers that fragment and turbulent reconnection
outfows. All of these processes act across, and encompass, multiple reconnection sites. We use
Magnetospheric Multi Scale four-point satellite observations to characterize the magnetic feld line
topology within a single reconnection current layer. We examine magnetopause reconnection where
the spacecraft encounter the Electron Difusion Region (EDR). We fnd fuctuating magnetic feld with
topology identical to that found for dynamically evolving vortices in hydrodynamic turbulence. The
turbulence is supported by an electron-magnetohydrodynamic (EMHD) fow in which the magnetic
feld is efectively frozen into the electron fuid. Accelerated electrons are found in the EDR edge where
we identify a departure from this turbulent topology, towards two-dimensional sheet-like structures.
This is consistent with a scenario in which sub-ion scale turbulence can suppress electron acceleration
within the EDR which would otherwise be possible in the electric feld at the X-line.
Publisher
Springer NatureCitation
Hnat, Chapman, Watkins. Topology of turbulence within collisionless plasma reconnection. Scientific Reports. 2023;13(1)Metadata
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