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Hybrid Simulation and Quasi-linear Theory of Bi-Kappa Proton Instabilities

Rodrigo A. López, Peter H. Yoon, A. F. Viñas, M. Lazar

2023The Astrophysical Journal12 citationsDOIOpen Access PDF

Abstract

Abstract The quasi-steady states of collisionless plasmas in space (e.g., in the solar wind and planetary environments) are governed by the interactions of charged particles with wave fluctuations. These interactions are responsible not only for the dissipation of plasma waves but also for their excitation. The present analysis focuses on two instabilities, mirror and electromagnetic ion cyclotron instabilities, associated with the same proton temperature anisotropy T ⊥ > T ∥ (where ⊥, ∥ are directions defined with respect to the local magnetic field vector). Theories relying on standard Maxwellian models fail to link these two instabilities (i.e., predicted thresholds) to the proton quasi-stable anisotropies measured in situ in a completely satisfactory manner. Here we revisit these instabilities by modeling protons with the generalized bi-Kappa (bi- κ power-law) distribution, and by a comparative analysis of a 2D hybrid simulation with the velocity-moment-based quasi-linear (QL) theory. It is shown that the two methods feature qualitative and, even to some extent, quantitative agreement. The reduced QL analysis based upon the assumption of a time-dependent bi-Kappa model thus becomes a valuable theoretical approach that can be incorporated into the present studies of solar wind dynamics.

Topics & Concepts

PhysicsSolar windProtonAstrophysical plasmaAnisotropyComputational physicsPlasmaDissipationSpace physicsClassical mechanicsStatistical physicsNuclear physicsQuantum mechanicsGeophysicsIonosphere and magnetosphere dynamicsSolar and Space Plasma DynamicsAtmospheric Ozone and Climate
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