Abstract
Abstract. Planar magnetic structures (PMSs) are periods in the solar wind during which interplanetary magnetic field vectors are nearly parallel to a single plane. One of the specific regions where PMSs have been reported are coronal mass ejection (CME)-driven sheaths. We use here an automated method to identify PMSs in 95 CME sheath regions observed in situ by the Wind and ACE spacecraft between 1997 and 2015. The occurrence and location of the PMSs are related to various shock, sheath, and CME properties. We find that PMSs are ubiquitous in CME sheaths; 85 % of the studied sheath regions had PMSs with the mean duration of 6 h. In about one-third of the cases the magnetic field vectors followed a single PMS plane that covered a significant part (at least 67 %) of the sheath region. Our analysis gives strong support for two suggested PMS formation mechanisms: the amplification and alignment of solar wind discontinuities near the CME-driven shock and the draping of the magnetic field lines around the CME ejecta. For example, we found that the shock and PMS plane normals generally coincided for the events where the PMSs occurred near the shock (68 % of the PMS plane normals near the shock were separated by less than 20° from the shock normal), while deviations were clearly larger when PMSs occurred close to the ejecta leading edge. In addition, PMSs near the shock were generally associated with lower upstream plasma beta than the cases where PMSs occurred near the leading edge of the CME. We also demonstrate that the planar parts of the sheath contain a higher amount of strong southward magnetic field than the non-planar parts, suggesting that planar sheaths are more likely to drive magnetospheric activity.
Highlights
Coronal mass ejections (CMEs) are giant clouds of plasma and magnetic field that are expelled from the Sun into the heliosphere
We found that the shock and Planar magnetic structures (PMSs) plane normals generally coincided for the events where the PMSs occurred near the shock (68 % of the PMS plane normals near the shock were separated by less than 20◦ from the shock normal), while deviations were clearly larger when PMSs occurred close to the ejecta leading edge
In this paper we have studied the occurrence and distribution of planar magnetic structures (PMSs) within 95 CMEdriven sheath regions and their association with the shock, sheath and ICME properties
Summary
Coronal mass ejections (CMEs) are giant clouds of plasma and magnetic field that are expelled from the Sun into the heliosphere. E. Palmerio et al.: PMSs in CME-driven sheaths gion forms gradually as the layers of interplanetary magnetic field (IMF) and solar wind plasma accumulate over several days it takes for a CME to travel from the Sun to the Earth. As the magnetic field piles up at the ejecta leading edge, the compression of the IMF reduces the field variations in the direction perpendicular to the surface of the ejecta, resulting in a structure that is nearly parallel to the CME surface (Neugebauer et al, 1993). Strong southward IMF periods during the PMS-related periods in a sheath drove a significant part of the intense storm on 17 March 2015 (Kataoka et al, 2015) It is still unclear how planarity in the sheath affects geoeffectivity, how PMSs are distributed within the sheath and what is their origin in different parts of the sheath.
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