Hwang, K.-J., Burch, J.L., Russell, C.T., Choi, E., Dokgo, K., Fear, R.C., Fuselier, S.A., Petrinec, S.M., Sibeck, D.G., Hasegawa, H., Fu, H., Oieroset, M., Escoubet, C.P., Giles, B.L., Khotyaintsev, Y., Graham, D.B., Gershman, D.J., Pollock, C.J., Ergun, R.E., Torbert, R.B. and Broll, J. (2021) Microscale processes determining macroscale evolution of magnetic flux tubes along Earth's magnetopause. Astrophysical Journal, 914 (1), [26]. (doi:10.3847/1538-4357/abf8b1).
Abstract
An important process affecting solar wind-Earth's magnetosphere coupling is nonsteady dayside magnetic reconnection, observationally evidenced by a flux transfer event (FTE) that shows a bipolar variation of the magnetic field component normal to the magnetopause. FTEs often consist of two interlinked flux tubes, but, local kinetic processes between the flux tubes are not understood in the context of the FTE structuring, evolution, and impact. An FTE observed by the Magnetospheric Multiscale mission on 2017 December 18 consisted of two flux tubes of different topology. One includes field lines with ends connected to the northern and southern hemispheres while the other includes field lines with both ends connected to the magnetosheath. Reconnection occurring at the flux-tube interface indicates how interacting flux tubes evolve into a flux rope with helical magnetic topology that is either closed or open. This study demonstrates a new aspect of how micro- to meso-scale dynamics occurring within FTEs determines their macroscale characteristics and evolution.
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