4.7 Article

Electrostatic Waves Around a Magnetopause Reconnection Secondary Electron Diffusion Region Modulated by Whistler and Lower-Hybrid Waves

Journal

GEOPHYSICAL RESEARCH LETTERS
Volume 50, Issue 18, Pages -

Publisher

AMER GEOPHYSICAL UNION
DOI: 10.1029/2023GL104905

Keywords

magnetic reconnection; electrostatic waves; cross-scale wave coupling; wave-particle interaction

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This study investigates electrostatic waves in a magnetopause reconnection event, specifically focusing on their coupling with lower-frequency electromagnetic waves. The anisotropy of energized electrons in the reconnection exhaust excites whistler waves, which in turn modulates parallel electron beam-mode waves near the current sheet mid-plane. In the separatrix region, parallel propagating electrostatic waves associated with field-aligned electron beams and perpendicular propagating electron cyclotron harmonic waves with loss cone distributions exhibit modulation frequencies in the lower-hybrid wave frequency range. These findings enhance our understanding of the characteristics and mechanisms of electrostatic waves in reconnection.
We investigate electrostatic waves in a magnetopause reconnection event around a secondary electron diffusion region. Near the current sheet mid-plane, parallel electron beam-mode waves are modulated by whistler waves. We conclude that the anisotropy of energized electrons in the reconnection exhaust excites whistler waves, which produce spatially modulated electron beams through nonlinear Landau resonance, and these beams excite beam-mode electrostatic waves. In the separatrix region, parallel propagating electrostatic waves associated with field-aligned electron beams and perpendicular propagating electron cyclotron harmonic waves with loss cone distributions exhibit modulation frequencies in the lower-hybrid wave (LHW) frequency range. We infer that LHWs scatter electrons to produce beams and alter loss cones to modulate electrostatic waves. The results advance our understanding about the regimes and mechanisms of electrostatic waves in reconnection, with an emphasis on their coupling with lower-frequency electromagnetic waves. Magnetic reconnection is an important energy dissipation process at the Earth's dayside magnetopause. In its central region, plasmas deviate from the thermal equilibrium and form structured distribution functions, which excite plasma waves. We investigate high-frequency electrostatic waves in an event, where the waves are associated with electron beam-plasma interaction or anisotropy of distribution functions. We find that electrostatic waves are driven and modulated by lower-frequency waves, as the latter alters the particle distribution functions. The results help us understand how various processes couple with each other to achieve the energy dissipation. Parallel electron beam-mode waves are modulated by whistler near the current sheet mid-plane, by driving beams through Landau resonanceElectron beam-mode and cyclotron waves are modulated by lower-hybrid waves near separatrices, with beam and loss cone distributions

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