Radiatively Cooled Magnetic Reconnection Experiments Driven by Pulsed Power

Magnetic reconnection is a ubiquitous process in astrophysical plasmas, responsible for the explosive conversion of magnetic energy into thermal and kinetic energy. In extreme astrophysical systems, such as black hole coronae and neutron star magnetospheres, radiative cooling modifies the energy par...

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Bibliographic Details
Published in:arXiv.org 2024-10
Main Author: Datta, Rishabh
Format: Article
Language:English
Subjects:
Black holes
Collisional plasmas
Cooling
Cooling rate
Cooling systems
Experiments
Exploding wires
Internal energy
Kinetic energy
Magnetohydrodynamics
Magnetospheres
Neutron stars
Numerical prediction
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Summary:Magnetic reconnection is a ubiquitous process in astrophysical plasmas, responsible for the explosive conversion of magnetic energy into thermal and kinetic energy. In extreme astrophysical systems, such as black hole coronae and neutron star magnetospheres, radiative cooling modifies the energy partition by rapidly removing internal energy. In this thesis, we perform experimental and computational studies of magnetic reconnection in a radiatively cooled regime, previously unexplored in reconnection studies. The Magnetic Reconnection on Z (MARZ) experiments consist of a dual exploding wire array, driven by a 20 MA peak, 300 ns rise time current generated by the Z pulsed-power machine (Sandia National Labs). The load generates oppositely-directed supersonic, super-Alfvénic, collisional plasma flows with anti-parallel magnetic fields, that generate a reconnection layer, in which the total cooling rate far exceeds the Alfvénic transit rate. Two- and three-dimensional simulations of the MARZ experiments are performed in GORGON, an Eulerian resistive magnetohydrodynamic code. The experiments confirm numerical predictions by providing evidence of plasmoid formation and strong radiative cooling. The findings in this thesis are of particular relevance to the generation of radiative emission from reconnection-driven astrophysical events, and to the global dynamics of reconnection in strongly cooled systems. The MARZ experiments also provide a novel platform for investigating radiative effects in high-energy-density and laboratory astrophysics experiments, and for validation of radiation magnetohydrodynamic and atomic spectroscopy codes.
ISSN:2331-8422