Abstract
AbstractWe present detailed analysis of the global relativistic electron dynamics as measured by total radiation belt content (RBC) during coronal mass ejection (CME) and corotating interaction region (CIR)‐driven geomagnetic storms. Recent work has demonstrated that the response of the outer radiation belt is consistent and repeatable during geomagnetic storms. Here we build on this work to show that radiation belt dynamics can be divided into two sequential phases, which have different solar wind dependencies and which when analyzed separately reveal that the radiation belt responds more predictably than if the overall storm response is analyzed as a whole. In terms of RBC, in every storm we analyzed, a phase dominated by loss is followed by a phase dominated by acceleration. Analysis of the RBC during each of these phases demonstrates that they both respond coherently to solar wind and magnetospheric driving. However, the response is independent of whether the storm response is associated with either a CME or CIR. Our analysis shows that during the initial phase, radiation belt loss is organized by the location of the magnetopause and the strength of Dst and ultralow frequency wave power. During the second phase, radiation belt enhancements are well organized by the amplitude of ultralow frequency waves, the auroral electroject index, and solar wind energy input. Overall, our results demonstrate that storm time dynamics of the RBC is repeatable and well characterized by solar wind and geomagnetic driving, albeit with different dependencies during the two phases of a storm.
Highlights
During intervals of enhanced solar wind driving, such as following the impact of interplanetary coronal mass ejections (CMEs) or corotating interaction regions (CIRs), the relativistic electron fluxes within the outer Van Allen radiation belt are extremely variable
We present detailed analysis of the global relativistic electron dynamics as measured by total radiation belt content (RBC) during coronal mass ejection (CME) and corotating interaction region (CIR)‐driven geomagnetic storms
We investigate storm time radiation belt dynamics driven by CMEs and CIRs utilizing data from Solar Anomalous and Magnetospheric Particle Explorer (SAMPEX) and the derived RBC index (Baker et al, 2004)
Summary
During intervals of enhanced solar wind driving, such as following the impact of interplanetary coronal mass ejections (CMEs) or corotating interaction regions (CIRs), the relativistic electron fluxes within the outer Van Allen radiation belt are extremely variable. In a statistical study of storm time radiation belt electron dynamics observed by the Van Allen Probes, Bingham et al (2018) found that CME‐driven storms, on average, showed greater radiation belt electron enhancements compared to CIR‐driven storms, consistent with Yuan and Zong (2012) These authors concluded that this difference was likely due to an earlier and deeper penetration of radiation belt seed electrons driven by enhanced convection and substorm activity during observed during CME‐driven storms (Baker et al, 1998; Jaynes et al, 2015). Storm time enhancements of relativistic electron fluxes in the outer radiation belt during storms have a strong contribution from solar wind energy input, substorms, and likely energization via ultralow frequency (ULF) and very low frequency (VLF) waves
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