Whistler Influence on the Overall Very Low Frequency Wave Intensity in the Upper Ionosphere

Zãhlava, J; Němec, F.; Pinçon, Jean Louis; Santolı́k, O.; Kolmašová, Ivana; Parrot, M.

doi:10.1029/2017ja025137

Cited by 12 publications

(23 citation statements)

References 55 publications

(68 reference statements)

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“…We can compare our median wave-electric-field spectral density with that observed by the survey mode on DEMETER (see nightime cases in figures 5c and 5d in Zahlava et al, 2018). They report latitude …”

Section: Composite Results: Wave Spectrum and Intensitymentioning

confidence: 79%

“…It must be due to the moving satellite to which the raypaths must connect, slicing through plasma structures along the raypath. All three of the clusters in Figure 12 are below 100 s 1/2 phase dispersion or~8 s 1/2 group dispersion D. This is in the range classified by the cited DEMETER (Zahlava et al, 2018) study as fractional hop due to terrestrial lightning. Figure 13 shows the time-integrated phase dispersion found by the automated algorithm within the two prolific records for the magnetic inclination at the satellite (a) −44.2°and (b) −2.2°.…”

Section: Journal Of Geophysical Research: Space Physicsmentioning

confidence: 77%

“…Figure 12 shows the time history of phase dispersions found by the automated algorithm within the two prolific records for the magnetic inclination at the satellite (a) −44.2°and (b) −2.2°. All three of the clusters in Figure 12 are below 100 s 1/2 phase dispersion or~8 s 1/2 group dispersion D. This is in the range classified by the cited DEMETER (Zahlava et al, 2018) study as fractional hop due to terrestrial lightning. We perform the search for optimal dechirps over phase dispersion, not over group dispersion D. The algorithm (Jacobson et al, 2016) can identify multiple phase dispersions simultaneously if needed.…”

Section: Journal Of Geophysical Research: Space Physicsmentioning

confidence: 79%

“…There have already been excellent and extensive surveys of whistler-wave intensity versus latitude, employing the Detection of Electromagnetic Emissions Transmitted from Earthquake Regions (DEMETER) satellite (see, e.g., Colman & Starks, 2013;Zahlava et al, 2018). DEMETER was Sun-syncronous and observed all latitudes, including the low latitudes (±13°geographic) of C/NOFS, twice a day: once sunlit in the local morning and once in local premidnight.…”

Section: Introductionmentioning

confidence: 99%

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Low‐Latitude Whistler‐Wave Spectra and Polarization From VEFI and CINDI Payloads on C/NOFS Satellite

et al. 2020

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The Communication/Navigation Outage Forecast System (C/NOFS) satellite's VEFI payload performed frequent recordings of the vector electric field in the band 0-16 kHz during the epoch 2008-2014. The Vector Electric Field Instrument (VEFI) was supported by ion-composition data from the Coupled Ion Neutral Dynamics Investigation (CINDI) instrument. We focus here on statistics of these "burst-mode" recordings, of which 6,890 (mostly~12-s duration) records meet stringent quality-control criteria, allowing inference of the wave vector k and its orientation relative to the Earth's magnetic field B 0 . The 6,890 records occur between ±13°(geographic) latitude and between~400-and 850-km altitude, mostly in the topside ionosphere. The wave activity is dominated by terrestrial lightning. We analyze the whistler-wave intensity and polarization for each pixel in the time-frequency spectrogram for each record. We then gather weighted statistics on wave polarization, naturally weighted by wave intensity. In this manner we arrive at statistical results that represent the bulk of the energy flow due to whistler waves. Despite rather nonstationary statistics, we can reach three empirical results.a We see no evidence of a low-latitude suppression of whistler-wave activity, in contrast to the predictions of models of transmission through a laminar ionosphere. b The wave vector polar angle is always in the range 40°to 90°from parallel to B 0 . This indicates that the propagation at low latitudes is dominated by oblique, not ducted, whistlers. c At the lowest magnetic latitudes, the wave vector polar angle with respect to B 0 becomes nearly 90°.

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Section: Composite Results: Wave Spectrum and Intensitymentioning

confidence: 79%

Section: Journal Of Geophysical Research: Space Physicsmentioning

confidence: 77%

Section: Journal Of Geophysical Research: Space Physicsmentioning

confidence: 79%

Section: Introductionmentioning

confidence: 99%

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Low‐Latitude Whistler‐Wave Spectra and Polarization From VEFI and CINDI Payloads on C/NOFS Satellite

et al. 2020

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“…Whistlers are important because they induce electron precipitation from the radiation belts (see Inan et al, ; Gemelos et al, ; Bourriez et al, , and references therein). Whistlers also significantly impact the overall wave intensity in the magnetosphere (Colman & Starks, ; Němec et al, ; Záhlava et al, ). This is specially the case during nighttime when the wave attenuation in the ionosphere is lower (Cohen et al, ; Graf et al, ).…”

Section: Introductionmentioning

confidence: 99%

Short‐Fractional Hop Whistler Rate Observed by the Low‐Altitude Satellite DEMETER at the End of the Solar Cycle 23

2019

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For the first time an evaluation of the whistler rate around the Earth is performed using results from the neural network aboard the microsatellite DEMETER. It is shown that the rate of whistlers with low dispersion calculated all around the Earth as a function of longitude vary between 1 and 6 s−1 during nighttime (22.30 LT) and between 0.5 and 0.7 s−1 during daytime (10.30 LT). The whistler rate is anticorrelated with the F10.7‐cm solar flux. A decrease by 25% of the solar flux corresponds to an increase of 62% (26%) of the averaged whistler rate calculated for the entire Earth during nighttime (daytime). Using this averaged whistler rate, the global lightning rate is estimated to be of the order of 123 s−1 (27 s−1) during nighttime (daytime). The main conclusion concerns the precipitation of the electrons in the radiation belt by interaction with the whistlers. It is shown that the decrease of the lightning activity at solar minimum (shown with the help of the Schumann resonances) is largely counterbalanced by the increase of the whistler rates in the upper part of the ionosphere due to the decrease of the ionospheric absorption.

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Lightning Contribution to Overall Whistler Mode Wave Intensities in the Plasmasphere

Zãhlava

Němec

Santolı́k

et al. 2019

Geophysical Research Letters

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Electromagnetic waves generated by lightning propagate into the plasmasphere as dispersed whistlers. They can therefore influence the overall wave intensity in space, which, in turn, is important for dynamics of the Van Allen radiation belts. We analyze spacecraft measurements in low‐Earth orbit as well as in high‐altitude equatorial region, together with a ground‐based estimate of lightning activity. We accumulate wave intensities when the spacecraft are magnetically connected to thunderstorms and compare them with measurements obtained when thunderstorms are absent. We show that strong lightning activity substantially affects the wave intensity in a wide range of L‐shells and altitudes. The effect is observed mainly between 500 Hz and 4 kHz, but its frequency range strongly varies with L‐shell, extending up to 12 kHz for L lower than 3. The effect is stronger in the afternoon, evening, and night sectors, consistent with more lightning and easier wave propagation through the ionosphere.

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Whistler Influence on the Overall Very Low Frequency Wave Intensity in the Upper Ionosphere

Cited by 12 publications

References 55 publications

Low‐Latitude Whistler‐Wave Spectra and Polarization From VEFI and CINDI Payloads on C/NOFS Satellite

Low‐Latitude Whistler‐Wave Spectra and Polarization From VEFI and CINDI Payloads on C/NOFS Satellite

Short‐Fractional Hop Whistler Rate Observed by the Low‐Altitude Satellite DEMETER at the End of the Solar Cycle 23

Lightning Contribution to Overall Whistler Mode Wave Intensities in the Plasmasphere

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