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Ion Nongyrotropy in Solar Wind Discontinuities

Anton V. Artemyev, V. Angelopoulos, I. Y. Vasko, Л. М. Зеленый

2020The Astrophysical Journal Letters10 citationsDOI

Abstract

Abstract Magnetic field fluctuations in the solar wind are essentially Alfvénic with a good correlation between plasma and magnetic field variations. One of the most investigated types of such fluctuations is (rotational) discontinuities, rapid rotations of the solar wind magnetic field, usually accompanied by velocity jumps, Δ v l , comparable to Alfvén speed jumps, Δ v A . Although models of stationary discontinuities predict , observations often show . This difference has previously been interpreted as: (1) a possible contribution of anisotropy that decreases Δ v A , or (2) a discontinuity non-stationarity due to residual magnetic energy. We propose an alternate interpretation: an ion nonadiabatic interaction with intense (thin) discontinuities that shapes the nongyrotropic ion distribution to include a nondiagonal term of the pressure tensor, with a cross-discontinuity gradient decreasing Δ v A . Using several examples of ARTEMIS observations of intense solar wind discontinuities, we demonstrate the existence of an ion population that contributes to such a nondiagonal pressure component with spatial profile and amplitude sufficient to significantly decrease Δ v A . The observed pressure nongyrotropy (a finite nondiagonal pressure component) balances the discontinuity configuration and can explain the paradox for intense discontinuities.

Topics & Concepts

Solar windClassification of discontinuitiesIonEnvironmental scienceMeteorologyPhysicsAerospace engineeringAstrobiologyEngineering physicsGeophysicsGeologyAstronomyEngineeringMathematicsPlasmaNuclear physicsMathematical analysisQuantum mechanicsIonosphere and magnetosphere dynamicsSolar and Space Plasma DynamicsLightning and Electromagnetic Phenomena
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