An automated detection method applied to simulated flare ribbon data identifies fine structures whose motions and flux distribution are consistent with plasmoid-mediated reconnection.
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3 Pith papers cite this work. Polarity classification is still indexing.
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UNVERDICTED 3representative citing papers
Boundary-driven MHD flux-braiding simulations at different Rm reveal Rm-dependent current sheet properties with fragmentation at high Rm consistent with plasmoid instability, supporting braiding for coronal heating.
Simulations of turbulent reconnection in relativistic jets show energy-independent acceleration time in the Fermi regime matching theory up to a Larmor radius threshold set by current sheet thickness, then energy-dependent drift regime.
citing papers explorer
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Automatic detection of Flare Ribbon Fine Structures as Proxies for Plasmoid Dynamics in Flare Reconnection
An automated detection method applied to simulated flare ribbon data identifies fine structures whose motions and flux distribution are consistent with plasmoid-mediated reconnection.
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Distribution of energy release events due to magnetic braiding
Boundary-driven MHD flux-braiding simulations at different Rm reveal Rm-dependent current sheet properties with fragmentation at high Rm consistent with plasmoid instability, supporting braiding for coronal heating.
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Particle Acceleration Time due to Turbulent-Induced Magnetic Reconnection
Simulations of turbulent reconnection in relativistic jets show energy-independent acceleration time in the Fermi regime matching theory up to a Larmor radius threshold set by current sheet thickness, then energy-dependent drift regime.