H. Arnold scite author profile

The first self-consistent simulations of electron acceleration during magnetic reconnection in a macroscale system are presented. Consistent with solar flare observations, the spectra of energetic electrons take the form of power laws that extend more than two decades in energy. The drive mechanism for these nonthermal electrons is Fermi reflection in growing and merging magnetic flux ropes. A strong guide field suppresses the production of nonthermal electrons by weakening the Fermi drive mechanism. For a weak guide field the total energy content of nonthermal electrons dominates that of the hot thermal electrons even though their number density remains small. Our results are benchmarked with the hard x-ray, radio, and extreme ultraviolet observations of the X8.2-class solar flare on September 10, 2017.

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A computational model for exploring particle acceleration during reconnection in macroscale systems

Drake

Arnold

Swisdak

et al. 2019

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A new computational model is presented suitable for exploring the self-consistent production of energetic electrons during magnetic reconnection in macroscale systems. The equations are based on the recent discovery that parallel electric fields are ineffective drivers of energetic particles during reconnection so that the kinetic scales which control the development of such fields can be ordered out of the equations.The resulting equations consist of a magnetohydrodynamic (MHD) backbone with the energetic component represented by macro-particles described by the guiding center equations. Crucially, the energetic component feeds back on the MHD equations so that the total energy of the MHD fluid and the energetic particles is conserved.

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Equilibrium Kinetic Theory of Weakly Anisotropic Embedded Thin Current Sheets

Sitnov

Arnold

2022

JGR Space Physics

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Large-scale parallel electric fields and return currents in a global simulation model

Arnold

Drake

Swisdak

et al. 2019

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A new computational model, kglobal, is being developed to explore energetic electron production via magnetic reconnection in macroscale systems. The model is based on the discovery that the production of energetic electrons during reconnection is controlled by Fermi reflection in large-scale magnetic fields and not by parallel electric fields localized in kinetic scale boundary layers. Thus, the model eliminates these boundary layers. However, although the parallel electric fields that develop around the magnetic x-line and associated separatrices are not important in producing energetic electrons, there is a large scale electric field that kickstarts the heating of low-energy electrons and drives the cold-electron return current that accompanies escaping energetic electrons in open systems. This macroscale electric field is produced by magnetic-field-aligned gradients in the electron pressure. We have upgraded kglobal to include this large-scale electric field while maintaining energy conservation. The new model is tested by exploring the dynamics of electron acoustic modes which develop as a consequence of the presence of two electron species: hot kinetic and cold fluid electrons. Remarkably, the damping of electron acoustic modes is accurately captured by kglobal. Additionally, it has been established that kglobal correctly describes the dynamics of the interaction of the parallel electric field with escaping hot electrons through benchmarking simulations with the Particle-In-Cell (PIC) code p3d.

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Limitations Imposed by Slip and Inertia Terms upon Stokes's Law for the Motion of Spheres through Liquids

Arnold

1911

Phys. Rev. (Series I)

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H. Arnold

Electron Acceleration during Macroscale Magnetic Reconnection

A computational model for exploring particle acceleration during reconnection in macroscale systems

Equilibrium Kinetic Theory of Weakly Anisotropic Embedded Thin Current Sheets

Large-scale parallel electric fields and return currents in a global simulation model

Limitations Imposed by Slip and Inertia Terms upon Stokes's Law for the Motion of Spheres through Liquids

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