Interaction of magnetospheric Alfvén waves with the ionosphere in the Pc1 frequency band

Fedorov, E. N.; Mazur, N. G.; Пилипенко, В. А.; Engebretson, M. J.

doi:10.1002/2015ja021020

Cited by 21 publications

(18 citation statements)

References 40 publications

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“…In Figure , the 22:35–23:25 UT plot (red line) suggests that the IAR remain relatively constant in magnitude from 3 Hz to 12 Hz, once the SR is accounted for. This observation is in disagreement with much of the modeling work on IAR, which usually suggest a rapid decrease of IAR magnitude with frequency (e.g., Fedorov, Mazur, Pilipenko, & Engebretson, ; Fedorov, Mazur, Pilipenko, & Baddeley, ). However, Schekotov et al () and Fedorov, Mazur, Pilipenko, and Baddeley () suggest alternative mechanisms for IAR related to generation of fields from local lightning storms within 1,000 km.…”

Section: Discussioncontrasting

confidence: 79%

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Observation of Ionospheric Alfvén Resonances at 1–30 Hz and Their Superposition With the Schumann Resonances

Beggan

Musur

2018

JGR Space Physics

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Long-term measurements of the high-frequency magnetic field (0.1-100 Hz) have been made at Eskdalemuir Observatory in the United Kingdom since September 2012. We analyze five years of dynamic spectrograms to examine the occurrence and behavior of the Schumann and ionospheric Alfvén resonances (IAR) and Pc1 pulsations. The resonances, observed as diffuse bands, arise from reflections of energy both within the Earth-ionosphere cavity and from the nonlinear conductivity gradient of the ionosphere. Schumann Resonances (SR) occur continuously but IAR are observed to arise at local nighttime in ∼50% of days in the data set. Typically, IAR are found at frequencies of 1-8 Hz, but we find them extending out to 30 Hz and strongly superimposing over the first three Schumann resonances around 9% of the time. These phenomena include constructive and destructive interference, nonlinear frequency changes over the span of several hours, and polarity enhancements. In addition, the magnitude of the IAR does not decline rapidly with frequency as often proposed. We find that the IAR and their superposition with SR are strongly controlled by season and geomagnetic activity. We compare 6 days with the most unusual IAR behavior in the data set to ionosonde measurements of f 0 F 2 , a proxy for ionospheric conductivity but find little correlation. We suggest that, as current theoretical modeling does not account for these observations, further work is needed to understand how they arise. Plain Language Summary Measurements of the very rapid changes of the Earth's magnetic field(changes at a rate of between 1 and 50 times per second) show very weak repeating patterns. They are caused by magnetic fields from lightning strikes in thunderstorms near the equator. The lightning strikes are strong enough to "echo" around the globe repeatedly for a few seconds before fading, similar to the sound from a resonating bell. These patterns repeat at fixed periods of around 8, 14, and 21 times per second and are called the Schumann resonances. At night time, other patterns appear in the measurements caused by magnetic waves temporarily trapped in the upper atmosphere (called the ionosphere) between heights of 100 and 1,000 km. These patterns are labeled the ionospheric Alfvén resonances are a relatively unstudied feature of the Earth's magnetic field. We looked at these patterns in magnetic field data collected from Eskdalemuir Observatory in the United Kingdom over the past 5 years. We checked how often these types of patterns occurred and found a link to the seasons and how active, in general, the magnetic field is. We also found unusual and currently unexplained patterns including interference between the Schumann and ionospheric Alfvén resonances.

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Section: Discussioncontrasting

confidence: 79%

“…As an interesting geophysical phenomenon, they have been extensively studied and modeled to understand their origin (e.g., Fedorov et al, ; Lysak, , ). In terms of observations, Belyaev et al () looked at the properties of IAR at high latitude ( L > 5), while Bösinger et al (, ) examined them at low latitudes ( L = 1.3).…”

Section: Introductionmentioning

confidence: 99%

Observation of Ionospheric Alfvén Resonances at 1–30 Hz and Their Superposition With the Schumann Resonances

Beggan

Musur

2018

JGR Space Physics

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“…These waves can be reflected at the ionosphere due to the mismatch between the Alfvén conductance and that of the ionosphere. There have been many theoretical studies on Alfvén wave reflection by the ionosphere [e.g., Knudsen et al , ; Lysak , ; Vogt , ; Fedorov et al , ]. For the simplest case of reflection we may refer to the approach of Burke et al [, and references therein], which can be summarized as follows.…”

Section: Introductionmentioning

confidence: 99%

Alfvén waves in the auroral region, their Poynting flux, and reflection coefficient as estimated from Swarm observations

et al. 2017

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The European Space Agency's Swarm constellation can measure electric field, magnetic field, and plasma density on board multiple satellites at altitudes of about 500 km. Based on the data set at high latitudes, we estimate Poynting flux and ionospheric reflection coefficients of Alfvén waves with scale sizes of about 10–100 km. The reflection coefficients are generally higher surrounding the cusp and auroral regions than in the polar cap and higher in the summer than in the winter hemisphere. In the summer (winter) hemisphere the reflection coefficients generally peak on the dayside (nightside). Distributions of the reflection coefficients are not controlled by those of in situ plasma density. Poynting flux of the Alfvén waves maximizes surrounding the cusp and near‐midnight auroral region with magnitudes approaching 1 mW/m2, which are consistent with previous magnetospheric observations. The observed Poynting flux is downward on average for both hemispheres, and the magnitudes do not exhibit clear hemispheric asymmetry.

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“…The coupled MHD equations describing these modes in an anisotropic collisional plasma can be found in Waters et al (2007) and Fedorov et al (2016). The vertical profile of local of the ionospheric parameters (conductivity tensor, Alfven velocity, electron mobility tensor, etc.)…”

Section: Possible Mechanisms Of Tec Modulation By Mhd Wavesmentioning

confidence: 99%

Modulation of the ionosphere by Pc5 waves observed simultaneously by GPS/TEC and EISCAT

et al. 2016

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Earlier studies demonstrated that the monitoring of the ionospheric total electron content (TEC) by global satellite navigation systems is a powerful method to study the propagation of transient disturbances in the ionosphere, induced by internal gravity waves. This technique has turned out to be sensitive enough to detect ionospheric signatures of magnetohydrodynamic waves as well. However, the effect of TEC modulation by ULF waves is not well examined as a responsible mechanism has not been firmly identified. During periods with intense Pc5 waves distinct pulsations with the same periodicity were found in the TEC data from high-latitude GPS receivers in Scandinavia. We analyze jointly responses in TEC variations and EISCAT ionospheric parameters to global Pc5 pulsations during the recovery phase of the strong magnetic storms on October 31, 2003. Comparison of periodic fluctuations of the electron density at different altitudes from EISCAT data shows that main contribution into TEC pulsations is provided by the lower ionosphere, up to ~150 km, that is the E-layer and lower F-layer. This observational fact favors the TEC modulation mechanism by field-aligned plasma transport induced by Alfven wave. Analytical estimates and numerical modeling support the effectiveness of this mechanism. Though the proposed hypothesis is basically consistent with the analyzed event, the correspondence between magnetic and ionospheric oscillations is not always perfect, so further studies need to be conducted to understand fully the TEC modulations associated with Pc5 pulsations.

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Interaction of magnetospheric Alfvén waves with the ionosphere in the Pc1 frequency band

Cited by 21 publications

References 40 publications

Observation of Ionospheric Alfvén Resonances at 1–30 Hz and Their Superposition With the Schumann Resonances

Observation of Ionospheric Alfvén Resonances at 1–30 Hz and Their Superposition With the Schumann Resonances

Alfvén waves in the auroral region, their Poynting flux, and reflection coefficient as estimated from Swarm observations

Modulation of the ionosphere by Pc5 waves observed simultaneously by GPS/TEC and EISCAT

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