Global Characteristics of Electromagnetic Ion Cyclotron Waves Deduced From Swarm Satellites

Kim, Hyangpyo; Hwang, Junga; Park, Jaeheung; Bortnik, J.; Lee, Jaejin

doi:10.1002/2017ja024888

Cited by 19 publications

(53 citation statements)

References 52 publications

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“…The prenoon sector (10:00–12:00 MLT) shows higher occurrence rate than the afternoon sector (12:00–14:00 MLT). The local time distribution of the occurrence rate of storm time EMIC waves are different from those of statistical results by H. Kim et al () based on Swarm wave events from December 2013 to June 2017. In their work quite comparable occurrence distribution was found around the noon and midnight, while in the present work, we found maximum occurrence in the premidnight sector when compared to the prenoon, postnoon, and postmidnight sectors.…”

Section: Observationscontrasting

confidence: 89%

“…Kim et al, ; Park et al, ), Combined Release and Radiation Effects Satellite (CRRES; e.g., Halford et al, ; Min et al, ; Meredith et al, ), Dynamic Explorer 1 (Erlandson & Ukhorskiy, ), Van Allen Probes (VAPs; Saikin et al, ; D. Wang et al, ; Yu et al, ), and Magenetospheric Multiscale mission (X. Y. Wang et al, ). Ionospheric EMIC waves have been statistically studied using data from the Magnetic Field Satellite, Freja, Dynamic Explorer 2, Challenging Minisatellite Payload, and Swarm satellites (e.g., Erlandson & Anderson, ; Iyemori & Hayashi, ; H. Kim et al, ; Mursula et al, ; Park et al, ). These studies found that the source regions of EMIC waves varied over a wide range of magnetic local times (MLTs) from 03:00 to 20:00 MLT and over the L shells from 2 to 13 R E , which correspond to the range of invariant latitudes (ILat) from 45° (midlatitudes) to 74° (auroral zone).…”

Section: Introductionmentioning

confidence: 99%

“…Halford et al () considered how the occurrence of waves varied with the phase of the storms and found that EMIC waves occurring during the recovery phase have plasma and wave characteristics that were more similar to those found during quiet conditions than to those observed during the main phase. Using 3 years of Swarm A observations in the ionosphere, H. Kim et al () found that EMIC waves exhibited some correlation with geomagnetic activity, with a tendency to occur during the late recovery phase of the storms at low Earth orbit. However, their work did not mention differences by hemisphere/local time or the three wave bands, which are the objectives in the present study.…”

Section: Introductionmentioning

confidence: 99%

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Storm Time EMIC Waves Observed by Swarm and Van Allen Probe Satellites

Wang

Lühr

et al. 2019

JGR Space Physics

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The temporal and spatial evolution of electromagnetic ion cyclotron (EMIC) waves during the magnetic storm of 21–29 June 2015 was investigated using high‐resolution magnetic field observations from Swarm constellation in the ionosphere and Van Allen Probes in the magnetosphere. Magnetospheric EMIC waves had a maximum occurrence frequency in the afternoon sector and shifted equatorward during the expansion phase and poleward during the recovery phase. However, ionospheric waves in subauroral regions occurred more frequently in the nighttime than during the day and exhibited less obvious latitudinal movements. During the main phase, dayside EMIC waves occurred in both the ionosphere and magnetosphere in response to the dramatic increase in the solar wind dynamic pressure. Waves were absent in the magnetosphere and ionosphere around the minimum SYM‐H. During the early recovery phase, He+ band EMIC waves were observed in the ionosphere and magnetosphere. During the late recovery phase, H+ band EMIC waves emerged in response to enhanced earthward convection during substorms in the premidnight sector. The occurrence of EMIC waves in the noon sector was affected by the intensity of substorm activity. Both ionospheric wave frequency and power were higher in the summer hemisphere than in the winter hemisphere. Waves were confined to an MLT interval of less than 5 hr with a duration of less than 186 min from coordinated observations. The results could provide additional insights into the spatial characteristics and propagation features of EMIC waves during storm periods.

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Section: Observationscontrasting

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Storm Time EMIC Waves Observed by Swarm and Van Allen Probe Satellites

Wang

Lühr

et al. 2019

JGR Space Physics

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“…Electromagnetic ion cyclotron (EMIC) waves are in the typical frequency range of 0.1-5 Hz that correspond to Pc1 pulsations on the ground. Generally, in the magnetosphere, EMIC waves can be excited by the cyclotron instability of hot ions (1-100 keV) with temperature anisotropy (T ⊥ > T // ) near the Earth's magnetic equator -particularly, in the region with a large plasma density and weak magnetic field, such as the plasmapause, ring current, and plasma sheet (Cornwall et al, 1965;Erlandson et al, 1993;Horne and Thorne, 1993;Anderson et al, 1996;Lin et al, 2014). Previous studies indicate that hot ion temperature anisotropy (T ⊥ > T // ) near the Earth's magnetic equator can be caused by several possible mechanisms, such as plasmapause expanding into the ring current region during the storm recovery phase (Cornwall et al, 1970;Russell and Thorne, 1970), mid-energy ions penetrating into the ring current region from the plasma sheet (Bossen et al, 1976), the solar wind dynamic pressure enhancement, or the magnetosphere compression (Olson and Lee, 1983;Anderson and Hamilton, 1993;McCollough et al, 2010;Usanova et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Ionospheric Pc1 waves during a storm recovery phase observed by the China Seismo-Electromagnetic Satellite

Gou

Zhang

et al. 2020

Ann. Geophys.

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Abstract. During the storm recovery phase on 27 August 2018, the China Seismo-Electromagnetic Satellite (CSES) detected Pc1 wave activities in both the Northern Hemisphere and Southern Hemisphere in the high-latitude, post-midnight ionosphere with a central frequency of about 2 Hz. Meanwhile, the typical Pc1 waves were simultaneously observed for several hours by the Sodankylä Geophysical Observatory (SGO) stations on the ground. In this paper, we study the propagation characteristics and possible source regions of those waves. Firstly, we find that the Pc1 waves observed by the satellites exhibited mixed polarisation, and the wave normal is almost parallel with the background magnetic field. The field-aligned Poynting fluxes point downwards in both hemispheres, implying that the satellites are close to the wave injection regions in the ionosphere at about L=3. Furthermore, we also find that the estimated position of the plasmapause calculated by models is almost at L=3. Therefore, we suggest that the possible sources of waves are near the plasmapause, which is consistent with previous studies in that the outward expansion of the plasmasphere into the ring current during the recovery phase of geomagnetic storms may generate electromagnetic ion cyclotron (EMIC) waves, and these EMIC waves propagate northwards and southwards along the background magnetic field to the ionosphere at about L=3. Additionally, the ground station data show that Pc1 wave power attenuates with increasing distance from L=3, supporting the idea that the CSES observes the wave activities near the injection region. The observations are unique in that the Pc1 waves are observed in the ionosphere in nearly conjugate regions where transverse Alfvén waves propagate down into the ionosphere.

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“…In the context of the Earth's radiation belt, much attention is paid on low‐frequency electromagnetic (EM) waves, including ultralow frequency waves, whistler‐mode chorus, plasmaspheric hiss, EM ion cyclotron, and magnetosonic waves. The reason is that these waves are known to play important roles as acceleration and loss mechanisms for electrons in the relativistic energy range (Bortnik & Thorne, , ; Claudepierre et al, ; Hwang et al, ; Kim et al, ; Li et al, ; Meredith et al, ; Ni et al, ; Nishimura et al, ; Santolík et al, ; Summers et al, ; Thorne et al, , ; Ukhorskiy et al, ). The occurrences of these low‐frequency waves are, however, not pervasive, and their excitations are highly correlated with geomagnetic activity levels.…”

Section: Introductionmentioning

confidence: 99%

High‐Frequency Thermal Fluctuations and Instabilities in the Radiation Belt Environment

Hwang

Yoon

2018

JGR Space Physics

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This paper overviews the electrostatic and electromagnetic theories of spontaneous emission in magnetized plasma as they relate to measured electric and magnetic field fluctuations in quiet time radiation belt and ring current region. The pervasively detected high-frequency fluctuations in the upper-hybrid frequency range as well as the background low-frequency range spectral profile in the whistler mode range are explained within the context of the spontaneous emission theory. The quasilinear calculation of loss cone instability is also carried out in order to validate the assumption of spontaneous emission model. It is shown that the saturated wave amplitudes associated with the upper-hybrid and multiple-harmonic cyclotron instability are quite low, indicating that the theoretical explanation based upon the assumption of spontaneous emission theory may be adequate for understanding the observed background fluctuations during quiet times. Plain Language SummarySince hot electrons constitute only a small fraction of the total electron number density in the space plasma, the general thought has been that the upper-hybrid fluctuations are useful only as a tool for indirectly measuring the cold electron number density. However, the data from the Van Allen Probes showed that upper-hybrid electrostatic fluctuations pervasively and ubiquitously exist in the radiation belts. From there, we proved that the presence of hot electrons and upper-hybrid fluctuations are mutually related phenomenon. We believe that it is the high-frequency electrostatic fluctuations that are constantly emitted and reabsorbed by the hot electrons, which allow these radiation belt electrons to remain inside the outer radiation belt for such a long time.n 0 e 2 ∕( m e ) and f c = eB 0 ∕(2 m e c) are the plasma frequency and electron cyclotron frequency, respectively. Here e, n 0 , B 0 , m e , and c represent the unit electric charge, ambient number density, ambient magnetic field intensity, electron rest mass, and the speed of light in vacuo, respectively. The multiple harmonic cyclotron emissions are also known in the literatures as the (n + 1∕2)f c emissions, and such emissions have been detected by the GEOTAIL and the Van Allen Probes.

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Global Characteristics of Electromagnetic Ion Cyclotron Waves Deduced From Swarm Satellites

Cited by 19 publications

References 52 publications

Storm Time EMIC Waves Observed by Swarm and Van Allen Probe Satellites

Storm Time EMIC Waves Observed by Swarm and Van Allen Probe Satellites

Ionospheric Pc1 waves during a storm recovery phase observed by the China Seismo-Electromagnetic Satellite

High‐Frequency Thermal Fluctuations and Instabilities in the Radiation Belt Environment

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