A current disruption mechanism in the neutral sheet for triggering substorm expansions

Details A current disruption mechanism in the neutral sheet for triggering substorm expansions A current disruption mechanism in the neutral sheet for triggering substorm expansions

Dec 1989

adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=1989jhu..rept.....l&link_type=abstract

Final Report Johns Hopkins Univ., Laurel, MD. Applied Physics Lab.

Physics

Broadband, Computerized Simulation, Current Sheets, Electromagnetic Noise, Magnetic Storms, Magnetohydrodynamic Stability, Neutral Sheets, Wave Dispersion, Boundary Conditions, Boundary Layers, Electric Field Strength, Electron Beams, Ion Beams, Plasma Layers

Scientific paper

Two main areas were addressed in support of an effort to understand mechanism responsible for the broadband electrostatic noise (BEN) observed in the magnetotail. The first area concerns the generation of BEN in the boundary layer region of the magnetotail whereas the second area concerns the occassional presence of BEN in the neutral sheet region. For the generation of BEN in the boundary layer region, a hybrid simulation code was developed to perform reliable longtime, quiet, highly resolved simulations of field aligned electron and ion beam flow. The result of the simulation shows that broadband emissions cannot be generated by beam-plasma instability if realistic values of the ion beam parameters are used. The waves generated from beam-plasma instability are highly discrete and are of high frequencies. For the plasma sheet boundary layer condition, the wave frequencies are in the kHz range, which is incompatible with the observation that the peak power in BEN occur in the 10's of Hz range. It was found that the BEN characteristics are more consistent with lower hybrid drift instability. For the occasional presence of BEN in the neutral sheet region, a linear analysis of the kinetic cross-field streaming instability appropriate to the neutral sheet condition just prior to onset of substorm expansion was performed. By solving numerically the dispersion relation, it was found that the instability has a growth time comparable to the onset time scale of substorm onset. The excited waves have a mixed polarization in the lower hybrid frequency range. The imposed drift driving the instability corresponds to unmagnetized ions undergoing current sheet acceleration in the presence of a cross-tail electric field. The required electric field strength is in the 10 mV/m range which is well within the observed electric field values detected in the neutral sheet during substorms. This finding can potentially account for the disruption of cross-tail current and its diversion to the ionosphere to form the substorm current wedge. Furthermore, a number of features associated with substorm expansion onset can be understood based on this substorm onset scenario.

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