Acceleration of ions by electric field pulses in the inner magnetosphere

Artemyev, А. V.; Liu, Jiang; Angelopoulos, V.

doi:10.1002/2015ja021160

Cited by 24 publications

(42 citation statements)

References 67 publications

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“…The electric field magnitude is typically 3 times greater for the former than for the latter. This supports previous models suggesting that injections result from a DFB's electric field directly accelerating or ushering particles into the inner magnetosphere Gabrielse et al, 2012;Birn et al, 2013;Artemyev et al, 2015]. Consistent with their electric field difference, DFBs with injection move faster than DFBs without.…”

Section: Summary and Discussionsupporting

confidence: 88%

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Dipolarizing flux bundles in the cis‐geosynchronous magnetosphere: Relationship between electric fields and energetic particle injections

et al. 2016

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Dipolarizing flux bundles (DFBs) are small flux tubes (typically <3 RE in XGSM and YGSM) in the nightside magnetosphere that have magnetic field more dipolar than the background. Although DFBs are known to accelerate particles, creating energetic particle injections outside geosynchronous orbit (trans‐GEO), the nature of the acceleration mechanism and the importance of DFBs in generating injections inside geosynchronous orbit (cis‐GEO) are unclear. Our statistical study of cis‐GEO DFBs using data from the Van Allen Probes reveals that just like trans‐GEO DFBs, cis‐GEO DFBs occur most often in the premidnight sector, but their occurrence rate is ~1/3 that of trans‐GEO DFBs. Half the cis‐GEO DFBs are accompanied by an energetic particle injection and have an electric field 3 times stronger than that of the injectionless half. All DFB injections are dispersionless within the temporal resolution considered (11 s). Our findings suggest that these injections are ushered or produced locally by the DFB, and the DFB's strong electric field is an important aspect of the injection generation mechanism.

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Section: Summary and Discussionsupporting

confidence: 88%

“…(Note that our electric fields are smaller than the values of Artemyev et al . [] because ours are averages over 1 min. The peaks of our electric fields are up to 42 mV/m.)…”

Section: Summary and Discussionmentioning

confidence: 99%

Dipolarizing flux bundles in the cis‐geosynchronous magnetosphere: Relationship between electric fields and energetic particle injections

et al. 2016

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“…Multiple models have been proposed to explain observations of energetic particle injections (e.g., Artemyev et al, 2015;Birn et al, 1998;Gabrielse et al, 2012Gabrielse et al, , 2016Gabrielse et al, 2017;Li et al, 1998;Li et al, 2003;Mauk & McIlwain, 1974;Reeves et al, 1991;Sarris et al, 2002;Ukhorskiy et al, 2017). Previous studies (e.g., Angelopoulos et al, 2008;Baker et al, 1996) suggest that some energetic particle injections result from earthward moving plasma (e.g., plasma bubbles or dipolarizing flux bundles) associated with a sharp enhancement in the z component of the magnetic field (i.e., dipolarization or dipolarization front).…”

Section: Introductionmentioning

confidence: 99%

Drift‐Dispersed Flux Dropouts of Energetic Electrons Observed in Earth's Middle Magnetosphere by the Magnetospheric Multiscale (MMS) Mission

Cohen

Mauk

Turner

et al. 2019

Geophysical Research Letters

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Energetic particle injections are characterized by dispersive or dispersionless increases in observed particle flux. Observations from National Aeronautics and Space Administration's Magnetospheric Multiscale (MMS) mission have revealed transient events displaying injection‐like dispersed reductions in energetic (~30–600 keV) electron flux in the dawnside magnetosphere. Although initially believed to be the result of magnetopause losses, drift tracing of the electrons suggests a source for these drift‐dispersed flux dropouts in the near‐to‐postmidnight magnetotail suggesting that they are likely related to similar signatures previously observed at geosynchronous orbit. We suggest that the dozen examples presented are signatures of “flux‐reduced injections” resulting from earthward injection in the presence of a negative phase space density radial gradient as supported by observed phase space density versus L‐shell profiles. These events also display varying pitch angle responses inconsistent with a singular loss mechanism, leading to the suggestion that they result from preconditioning of the magnetotail source region prior to the injection.

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“…Such enhancements result most likely from particle acceleration by DFBs. This acceleration can be either adiabatic (Ashour‐Abdalla et al, ; Deng et al, ; Fu et al, ; Runov et al, ), most simply understood as caused by the electric field accompanying moving DFBs (e.g., Artemyev et al, ; Gabrielse et al, ; Zhou et al, ), or nonadiabatic due to large amplitude waves observed in the DFB vicinity (Zhou et al, ). For some DFBs that can penetrate into the inner magnetosphere, the electric field related to the DFB evolution can still be large and lead to significant local particle acceleration (Liu et al, ).…”

Section: Introductionmentioning

confidence: 99%

Ultralow Frequency Waves Deep Inside the Inner Magnetosphere Driven by Dipolarizing Flux Bundles

et al. 2017

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Dipolarizing flux bundles (DFBs) are small flux tubes (typical cross‐tail scale of 1–3 RE) in the nightside magnetosphere that have magnetic field more dipolar than the background. They are generated at or beyond 20 RE downtail and then travel earthward. Although DFBs usually stop before reaching the geosynchronous orbit (GEO), they may still transfer some portion of their energy into the inner magnetosphere by radiating ULF waves. We show the clearest evidence of this process, to date, using in situ data from a fleet of spacecraft and ground stations. We illustrate that a typical DFB stopped before reaching GEO but excited Pi2 waves that filled a volume of space extending from the plasma sheet to deep inside the plasmasphere. This event provides the first in situ, direct link between stopped DFBs and ULF waves deep inside the inner magnetosphere (as deep as L = 3). The waves were attenuated when traveling away from the DFB, but even at L = 3 (XGSM = −2.2), they were still traveling with a significant earthward Poynting flux. In addition, we observed evidence of interaction between these waves and electrons at GEO.

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Acceleration of ions by electric field pulses in the inner magnetosphere

Cited by 24 publications

References 67 publications

Dipolarizing flux bundles in the cis‐geosynchronous magnetosphere: Relationship between electric fields and energetic particle injections

Dipolarizing flux bundles in the cis‐geosynchronous magnetosphere: Relationship between electric fields and energetic particle injections

Drift‐Dispersed Flux Dropouts of Energetic Electrons Observed in Earth's Middle Magnetosphere by the Magnetospheric Multiscale (MMS) Mission

Ultralow Frequency Waves Deep Inside the Inner Magnetosphere Driven by Dipolarizing Flux Bundles

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