Litcius/Paper detail

Plasmoid Formation and Strong Radiative Cooling in a Driven Magnetic Reconnection Experiment

R. Datta, K. M. Chandler, C. E. Myers, J. P. Chittenden, Aidan Crilly, C. Aragón, D. J. Ampleford, Jacob Banasek, Aaron Edens, W. Fox, Stephanie B. Hansen, Eric Harding, Christopher Jennings, Hantao Ji, Carolyn Kuranz, S. V. Lebedev, Quinn Looker, S. G. Patel, Andrew Porwitzky, Gabriel Shipley, Dmitri Uzdensky, David Yager-Elorriaga, Jack Hare

2024Physical Review Letters10 citationsDOIOpen Access PDF

Abstract

We present the first experimental study of plasmoid formation in a magnetic reconnection layer undergoing rapid radiative cooling, a regime relevant to extreme astrophysical plasmas. Two exploding aluminum wire arrays, driven by the Z machine, generate a reconnection layer (S_{L}≈120) in which the cooling rate far exceeds the hydrodynamic transit rate (τ_{hydro}/τ_{cool}>100). The reconnection layer generates a transient burst of >1 keV x-ray emission, consistent with the formation and subsequent rapid cooling of the layer. Time-gated x-ray images show fast-moving (up to 50 km s^{-1}) hotspots in the layer, consistent with the presence of plasmoids in 3D resistive magnetohydrodynamic simulations. X-ray spectroscopy shows that these hotspots generate the majority of Al K-shell emission (around 1.6 keV) prior to the onset of cooling, and exhibit temperatures (170 eV) much greater than that of the plasma inflows and the rest of the reconnection layer, thus providing insight into the generation of high-energy radiation in radiatively cooled reconnection events.

Topics & Concepts

PlasmoidMagnetic reconnectionPhysicsRadiative coolingMagnetohydrodynamic drivePlasmaAstrophysicsRadiative transferMagnetohydrodynamicsAtomic physicsComputational physicsNuclear physicsOpticsAstrophysics and Cosmic PhenomenaIonosphere and magnetosphere dynamicsSolar and Space Plasma Dynamics