Pc1–Pc2 waves and energetic particle precipitation during and after magnetic storms: Superposed epoch analysis and case studies

Engebretson, M. J.; Lessard, M.; Bortnik, J.; Green, J.C.; Horne, Richard B.; Detrick, D. L.; Weatherwax, A. T.; Manninen, J.; Petit, N.; Posch, J. L.; Rose, M. C.

doi:10.1029/2007ja012362

Cited by 101 publications

(166 citation statements)

References 63 publications

(115 reference statements)

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“…Most events had frequencies between 0.2 and 1.4 Hz. The distribution of frequencies observed by ST5 is qualitatively similar to that shown in Figure 8 of Engebretson et al [2008], which grouped frequencies observed at Halley, Antarctica ( L = 4.56), according to UT and day after magnetic storm onset. Figure 9 (middle) shows the distribution of wave frequencies as a function of amplitude (from 5 to 110 nT); these show no evident correlation.…”

Section: Occurrence Patternssupporting

confidence: 74%

“…Pc1–2 wave activity has also been suggested as a possible prompt loss mechanism for relativistic electrons during the main phase of such storms [ Thorne et al , 2005]. However, although the few published satellite studies of Pc1–2 waves during storms report their occurrence during both main and recovery phases, such waves are consistently absent in ground data during the main and early recovery phases [e.g., Bräysy et al , 1998; Engebretson et al , 2008].…”

Section: Relation To Magnetic Stormsmentioning

confidence: 99%

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Temporal and spatial characteristics of Pc1 waves observed by ST5

et al. 2008

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[1] We present the results of a study of Pc1 waves (0.2-5 Hz) recorded by the three spacecraft of NASA's Space Technology 5 (ST5) mission, which operated in a dawn-dusk, 300 Â 4500 km Sun-synchronous orbit in a ''string-of-pearls'' configuration from 26 March through 23 June 2006. Regions with Pc1 wave activity are not only localized to rather narrow L shells but can appear and disappear on the time scales of $10 s to 10 min as examined by ST5. Only half of the 48 identified events were observed by all three spacecraft, and five events were observed by only one spacecraft. Only seven events were observed below L = 4, and only one was observed below L = 3.6, consistent with the relatively quiet geomagnetic conditions during this interval. The temporal occurrence distribution of Pc1 events was similar to that recorded at Halley, Antarctica (L = 4.56), during this same interval in that the number and intensity of events increased during magnetospheric compressions and during the recovery phase of magnetic storms, but they were reduced or absent during main phase and early recovery phase. This agreement suggests that if Pc1 events occur during main phase, their nearly universal absence in ground records cannot be ascribed to ionospheric screening effects or obscuration by irregular ULF noise generated in the ionosphere. These findings also suggest that although electromagnetic ion cyclotron waves might theoretically cause rapid depletion of radiation belt electrons during the main phase of storms, such waves cannot be assumed to occur during the main phase of all storms.

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Section: Occurrence Patternssupporting

confidence: 74%

Section: Relation To Magnetic Stormsmentioning

confidence: 99%

Temporal and spatial characteristics of Pc1 waves observed by ST5

et al. 2008

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“…At present there is a peculiarity that most MeV electron loss in the radiation belts occurs during main phase, yet on the ground EMIC power typically only appears during the recovery phase (e.g. Engebretson et al 2008;Bortnik et al 2008 and references therein). Whether this is due to internal reflection of EMIC waves in the magnetosphere (e.g.…”

Section: Electromagnetic Ion Cyclotron (Emic) Wavesmentioning

confidence: 97%

The Upgraded CARISMA Magnetometer Array in the THEMIS Era

et al. 2008

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This review describes the infrastructure and capabilities of the expanded and upgraded Canadian Array for Realtime InvestigationS of Magnetic Activity (CARISMA) magnetometer array in the era of the THEMIS mission. Formerly operated as the Canadian Auroral Network for the OPEN Program Unified Study (CANOPUS) magnetometer array until 2003, CARISMA capabilities have been extended with the deployment of additional fluxgate magnetometer stations (to a total of 28), the upgrading of the fluxgate magnetometer cadence to a standard data product of 1 sample/s (raw sampled 8 samples/s data stream available on request), and the deployment of a new network of 8 pairs of induction coils (100 samples per second). CARISMA data, GPS-timed and backed up at remote field stations, is collected using Very Small Aperture Terminal (VSAT) satellite internet in real-time providing a real-time monitor for magnetic activity on a continent-wide scale. Operating under the magnetic footprint of the THEMIS probes, data from 5 CARISMA stations at 29-30 samples/s also forms part of the formal THEMIS ground-based observatory (GBO) datastream. In addition to technical details, in this review we also outline some of the scientific capabilities of the CARISMA array for addressing all three of the scientific objectives of the THEMIS mission, namely: 1. Onset and evolution of the macroscale substorm instability, 414 I.R. Mann et al.2. Production of storm-time MeV electrons, and 3. Control of the solar wind-magnetosphere coupling by the bow shock, magnetosheath, and magnetopause. We further discuss some of the compelling questions related to these three THEMIS mission science objectives which can be addressed with CARISMA.

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“…In fact, there is still much current interest in ion pitch angle scattering by EMIC waves in the context of ring current dynamics. This is evidenced by the substantial literature that relates EMIC waves to ion precipitation resulting in ring current decay [e.g., Cornwall et al, 1970;Erlandson and Ukhorskiy, 2001;Summers, 2005;Fraser et al, 2006;Jordanova et al, 2007;Yahnin and Yahnina, 2007;Engebretson et al, 2008;Sakaguchi et al, 2008;Spasojevic et al, 2011;Xiao et al, 2012;Yuan et al, 2014]. In the present work, we treat EMIC wave-ion interactions as linear or quasi-linear, in common with most previous studies.…”

Section: Introductionmentioning

confidence: 69%

Limitation of energetic ring current ion spectra

Summers

Shi

2015

JGR Space Physics

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We address the problem of determining the limiting energetic ring current ion spectrum resulting from electromagnetic ion cyclotron (EMIC)‐wave‐ion interactions. We solve the problem in a relativistic regime, incorporating a cold background multi‐ion plasma component and without assuming a predetermined form for the ion energy distribution. The limiting (Kennel‐Petschek) spectrum is determined by the condition that the EMIC waves acquire a specified gain over a given convective length scale for all frequencies over which wave growth occurs. We find that the limiting ion spectrum satisfies an integral equation that must be solved numerically. However, at large particle energy E, the limiting spectrum takes the simple form J ∝ 1/E, E → ∞. Moreover, this 1/E spectral shape does not depend on the energetic ion in question nor on the background multi‐ion plasma composition. We provide numerical solutions for the limiting spectra for Earth‐like parameters. In addition, at four planets, Jupiter, Saturn, Uranus, and Neptune, we compare measured ion spectra with corresponding numerical limiting spectra. This paper parallels an earlier analogous study on the limitation of radiation belt electron spectra by whistler mode wave‐electron interactions.

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Pc1–Pc2 waves and energetic particle precipitation during and after magnetic storms: Superposed epoch analysis and case studies

Cited by 101 publications

References 63 publications

Temporal and spatial characteristics of Pc1 waves observed by ST5

Temporal and spatial characteristics of Pc1 waves observed by ST5

The Upgraded CARISMA Magnetometer Array in the THEMIS Era

Limitation of energetic ring current ion spectra

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