A study of Pc-5 ULF oscillations

Hudson, M. K.; Denton, R. E.; Lessard, M.; Miftakhova, E. G.; Anderson, R. R.

doi:10.5194/angeo-22-289-2004

Cited by 84 publications

(95 citation statements)

References 40 publications

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“…A1b, when it was already at higher L. Both spacecraft see approximately the same peak frequency 3.3 mHz by 22:01 UT, with power significantly lower at spacecraft B at that time and reduced further as it passes by 22:16 UT and moves further duskward. Figure 5 shows that the mHz ULF wave PSD attenuates away from the dayside, particularly clear for spacecraft B in panel (d), which has moved more duskward than A, as has been seen in many studies, with concentration of toroidal-mode power along the flanks of the magnetosphere and compressional in B (poloidal E φ ) power across the dayside; see, for example, Anderson et al (1992a, b) for a review of AMPTE CCE magnetometer measurements, Lessard et al (1999) for analysis of the local time distribution of AMPTE IRM magnetometer data, Hudson et al (2004) for CRRES magnetometer, Liu et al (2009) for THEMIS data, and Engebretson et al (1998) for ground magnetometer studies. Other LFM CME-shock event studies (Elkington et al, 2002 have confirmed the predominance of wave power on the dayside in the poloidal E φ component and discussed the need to include that longitudinal asymmetry in any prescribed ULF wave model of effects on radial transport and acceleration of electrons.…”

Section: October 2013mentioning

confidence: 99%

Magnetohydrodynamic modeling of three Van Allen Probes storms in 2012 and 2013

et al. 2015

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Abstract. Coronal mass ejection (CME)-shock compression of the dayside magnetopause has been observed to cause both prompt enhancement of radiation belt electron flux due to inward radial transport of electrons conserving their first adiabatic invariant and prompt losses which at times entirely eliminate the outer zone. Recent numerical studies suggest that enhanced ultra-low frequency (ULF) wave activity is necessary to explain electron losses deeper inside the magnetosphere than magnetopause incursion following CME-shock arrival. A combination of radial transport and magnetopause shadowing can account for losses observed at radial distances into L = 4.5, well within the computed magnetopause location. We compare ULF wave power from the Electric Field and Waves (EFW) electric field instrument on the Van Allen Probes for the 8 October 2013 storm with ULF wave power simulated using the Lyon-FedderMobarry (LFM) global magnetohydrodynamic (MHD) magnetospheric simulation code coupled to the Rice Convection Model (RCM). Two other storms with strong magnetopause compression, 8-9 October 2012 and 17-18 March 2013, are also examined. We show that the global MHD model captures the azimuthal magnetosonic impulse propagation speed and amplitude observed by the Van Allen Probes which is responsible for prompt acceleration at MeV energies reported for the 8 October 2013 storm. The simulation also captures the ULF wave power in the azimuthal component of the electric field, responsible for acceleration and radial transport of electrons, at frequencies comparable to the electron drift period. This electric field impulse has been shown to explain observations in related studies (Foster et al., 2015) of electron acceleration and drift phase bunching by the Energetic Particle, Composition, and Thermal Plasma Suite (ECT) instrument on the Van Allen Probes.

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Section: October 2013mentioning

confidence: 99%

Magnetohydrodynamic modeling of three Van Allen Probes storms in 2012 and 2013

et al. 2015

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“…Similarly to the definition used by Hudson et al [2004], here we characterize as narrowband Pc5 pulsations all magnetospheric oscillations with Df < 2 mHz at a given time, where bandwidth Df is the full width at half maximum. Such pulsations can be attributed either to the solar wind, acting as an external driver, or to internal plasma anisotropies, and are characterized by their azimuthal wave number, m [Dungey, 1954;Green, 1976], which is often indicative of the excitation mechanism.…”

Section: Introductionmentioning

confidence: 99%

A long‐duration narrowband Pc5 pulsation

Sarris

Singer

2009

J. Geophys. Res.

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[1] We report on a rare event of a narrowband ULF magnetospheric pulsation that is observed at geosynchronous orbit over five consecutive days in the recovery period of a magnetospheric storm, with frequencies ranging from 5 to 9 mHz. The pulsation displays distinctive localization, being observed over several hours of local time in the noon and postnoon sectors during successive passes of GOES-8 and GOES-9. Geotail, which is traversing the outer magnetosphere a couple of R E farther out from geosynchronous orbit at the time the pulsations are observed, shows no distinct narrowband fluctuation in the magnetic field, excluding oscillations in the solar wind as a possible source of the pulsations. On the ground, several of the IMAGE magnetometers observe pulsations with similar spectral characteristics. By performing a phase cross-spectrogram analysis on measurements from adjacent and latitudinally aligned ground stations we estimate the azimuthal mode number m of the pulsation, which we find to range between 20 and 55. Phase difference calculations indicate an eastward phase propagation of these pulsations. Density measurements from LANL spacecraft at geosynchronous orbit show evidence of a plasmasphere refilling process that is slower than usual, possibly associated with the observed slow frequency decrease and the unusually long lasting of the pulsations.

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“…These results have been confirmed by statistical analysis of GOES magnetic field data at geosynchronous orbit . Although excitation of ULF Pc4-5 waves has been traditionally attributed to the K-H instability, waves generated by this instability show minimum activity around noon near the subsolar stagnation region compared with the dawn and dusk sector (e.g., Anderson et al 1990;Zhu and Kivelson 1991;Lessard et al 1999;Hudson et al 2004;Takahashi and Ukhorsky 2007). The observations reported here, on the other hand, show that poloidal ULF waves associated with solar wind dynamic pressure pulses exhibit a maximum at local noon.…”

Section: Introductionmentioning

confidence: 99%

“…Sudden density or velocity increases in the solar wind produced by IP shocks lead to a step-like enhancement of the solar wind dynamic pressure and a sudden compression of Earth's dayside magnetosphere. The resulting magnetosonic waves launched into the magnetosphere (Wilken et al 1982;Kepko and Spence 2003;Hudson et al 2004;Claudepierre et al 2009) excite FLRs around magnetic local noon (Zong et al 2009a, b;) and interact with charged particles. Fig.…”

Section: Introductionmentioning

confidence: 99%

The interaction of ultra-low-frequency pc3-5 waves with charged particles in Earth’s magnetosphere

Zong

Rankin

Zhou

2017

Rev. Mod. Plasma Phys.

142

162

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One of the most important issues in space physics is to identify the dominant processes that transfer energy from the solar wind to energetic particle populations in Earth's inner magnetosphere. Ultra-low-frequency (ULF) waves are an important consideration as they propagate electromagnetic energy over vast distances with little dissipation and interact with charged particles via drift resonance and drift-bounce resonance. ULF waves also take part in magnetosphereionosphere coupling and thus play an essential role in regulating energy flow throughout the entire system. This review summarizes recent advances in the characterization of ULF Pc3-5 waves in different regions of the magnetosphere, including ion and electron acceleration associated with these waves.

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A study of Pc-5 ULF oscillations

Cited by 84 publications

References 40 publications

Magnetohydrodynamic modeling of three Van Allen Probes storms in 2012 and 2013

Magnetohydrodynamic modeling of three Van Allen Probes storms in 2012 and 2013

A long‐duration narrowband Pc5 pulsation

The interaction of ultra-low-frequency pc3-5 waves with charged particles in Earth’s magnetosphere

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