Enregistré dans:
Détails bibliographiques
Auteurs principaux: Datta, Rishabh, Crilly, Aidan J., Chittenden, Jeremy P., Chowdhry, Simran, Chandler, Katherine, Chaturvedi, Nikita, Myers, Clayton E., Fox, William R., Hansen, Stephanie B., Jennings, Christopher A., Ji, Hantao, Kuranz, Carolyn C., Lebedev, Sergey V., Uzdensky, Dmitri A., Hare, Jack D.
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2401.01795
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1866917558076047360
author Datta, Rishabh
Crilly, Aidan J.
Chittenden, Jeremy P.
Chowdhry, Simran
Chandler, Katherine
Chaturvedi, Nikita
Myers, Clayton E.
Fox, William R.
Hansen, Stephanie B.
Jennings, Christopher A.
Ji, Hantao
Kuranz, Carolyn C.
Lebedev, Sergey V.
Uzdensky, Dmitri A.
Hare, Jack D.
author_facet Datta, Rishabh
Crilly, Aidan J.
Chittenden, Jeremy P.
Chowdhry, Simran
Chandler, Katherine
Chaturvedi, Nikita
Myers, Clayton E.
Fox, William R.
Hansen, Stephanie B.
Jennings, Christopher A.
Ji, Hantao
Kuranz, Carolyn C.
Lebedev, Sergey V.
Uzdensky, Dmitri A.
Hare, Jack D.
contents Magnetic reconnection is an important process in astrophysical environments, as it re-configures magnetic field topology and converts magnetic energy into thermal and kinetic energy. In extreme astrophysical systems, such as black hole coronae and pulsar magnetospheres, radiative cooling modifies the energy partition by radiating away internal energy, which can lead to the radiative collapse of the layer. In this paper, we perform 2D & 3D simulations to model the MARZ (Magnetic Reconnection on Z) experiments, which are designed to access cooling rates in the laboratory necessary to investigate reconnection in a previously unexplored radiatively-cooled regime. These simulations are performed in GORGON, an Eulerian resistive magnetohydrodynamic code, which models the experimental geometry comprising two exploding wire arrays driven by 20 MA of current on the Z machine (Sandia National Laboratories). Radiative losses are implemented using non-local thermodynamic equilibrium tables computed using the atomic code Spk, and we probe the effects of radiation transport by implementing both a local radiation loss model and P$_{1/3}$ multi-group radiation transport. The load produces highly collisional, super-Alfvénic $(M_{A} \approx 1.5)$, supersonic $(M_S \approx 4-5)$ plasma flows which generate a reconnection layer ($L/δ \approx 100, S_L \approx 400$). The reconnection layer undergoes radiative collapse when the radiative losses exceed Ohmic and compressional heating $τ_{cool}^{-1}/τ_A^{-1} \approx 100$; this generates a cold strongly compressed current sheet, leading to an accelerated reconnection rate, consistent with theoretical predictions. Finally, the current sheet is unstable to the plasmoid instability, but the magnetic islands are extinguished by strong radiative cooling before ejection from the layer.
format Preprint
id arxiv_https___arxiv_org_abs_2401_01795
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Simulations of Radiatively Cooled Magnetic Reconnection Driven by Pulsed Power
Datta, Rishabh
Crilly, Aidan J.
Chittenden, Jeremy P.
Chowdhry, Simran
Chandler, Katherine
Chaturvedi, Nikita
Myers, Clayton E.
Fox, William R.
Hansen, Stephanie B.
Jennings, Christopher A.
Ji, Hantao
Kuranz, Carolyn C.
Lebedev, Sergey V.
Uzdensky, Dmitri A.
Hare, Jack D.
Plasma Physics
Magnetic reconnection is an important process in astrophysical environments, as it re-configures magnetic field topology and converts magnetic energy into thermal and kinetic energy. In extreme astrophysical systems, such as black hole coronae and pulsar magnetospheres, radiative cooling modifies the energy partition by radiating away internal energy, which can lead to the radiative collapse of the layer. In this paper, we perform 2D & 3D simulations to model the MARZ (Magnetic Reconnection on Z) experiments, which are designed to access cooling rates in the laboratory necessary to investigate reconnection in a previously unexplored radiatively-cooled regime. These simulations are performed in GORGON, an Eulerian resistive magnetohydrodynamic code, which models the experimental geometry comprising two exploding wire arrays driven by 20 MA of current on the Z machine (Sandia National Laboratories). Radiative losses are implemented using non-local thermodynamic equilibrium tables computed using the atomic code Spk, and we probe the effects of radiation transport by implementing both a local radiation loss model and P$_{1/3}$ multi-group radiation transport. The load produces highly collisional, super-Alfvénic $(M_{A} \approx 1.5)$, supersonic $(M_S \approx 4-5)$ plasma flows which generate a reconnection layer ($L/δ \approx 100, S_L \approx 400$). The reconnection layer undergoes radiative collapse when the radiative losses exceed Ohmic and compressional heating $τ_{cool}^{-1}/τ_A^{-1} \approx 100$; this generates a cold strongly compressed current sheet, leading to an accelerated reconnection rate, consistent with theoretical predictions. Finally, the current sheet is unstable to the plasmoid instability, but the magnetic islands are extinguished by strong radiative cooling before ejection from the layer.
title Simulations of Radiatively Cooled Magnetic Reconnection Driven by Pulsed Power
topic Plasma Physics
url https://arxiv.org/abs/2401.01795