A computational model for ion and electron energization during macroscale magnetic reconnection
Zhiyu Yin, J. F. Drake, M. Swisdak
Abstract
A set of equations is developed that extends the macroscale magnetic reconnection simulation model kglobal to include particle ions. The extension from earlier versions of kglobal, which included only particle electrons, requires the inclusion of the inertia of particle ions in the fluid momentum equation. The new equations will facilitate the exploration of the simultaneous non-thermal energization of ions and electrons during magnetic reconnection in macroscale systems. Numerical tests of the propagation of Alfvén waves and the growth of firehose modes in a plasma with anisotropic electron and ion pressure are presented to benchmark the new model.
Topics & Concepts
PhysicsMagnetic reconnectionElectronIonPlasmaInertiaAtomic physicsMomentum (technical analysis)AnisotropyComputational physicsClassical mechanicsMechanicsQuantum mechanicsFinanceEconomicsIonosphere and magnetosphere dynamicsSolar and Space Plasma DynamicsMagnetic confinement fusion research