Whistler interaction with field‐aligned density irregularities in the ionosphere: Refraction, diffraction, and interference

Woodroffe, J. R.; Streltsov, A. V.

doi:10.1002/2013ja019683

Cited by 12 publications

(15 citation statements)

References 30 publications

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“…It is ultimately possible for any wave normal angle in the range − θ G < θ < θ G (where

θ_{G} = \overset{- 1}{\cos} ω / 2 Ω

) to result from this mechanism, with rays originating at greater distances having larger θ at the center of the enhancement. The evolution of a ducted whistler is illustrated in Figure , which shows results from an electron magnetohydrodynamics simulation of whistler propagation [e.g., Woodroffe and Streltsov , ]. These results demonstrate how an initially field‐aligned whistler undergoes periodic “focusing” as it propagates within a field‐aligned density enhancement, resulting in the creation of a broad spectrum of different wave normal angles despite an initially field‐aligned signal.…”

Section: Theoretical Backgroundmentioning

confidence: 97%

“…The propagation of a whistler inside a density enhancement has been described in detail by Woodroffe and Streltsov []. The key idea is that even if the wave is initially field aligned, the transverse density structure causes the wave vector to develop a perpendicular component in the direction of the density variation.…”

Section: Theoretical Backgroundmentioning

confidence: 99%

“…The azimuthal propagation angle (Figure e) also exhibits a characteristic variation, going from ∼90° before encountering the enhancement to ∼0 ∘ within the enhancement, to ∼−90° on the other side. This is what would occur if the waves were being locally refracted toward density enhancement from outside the point where trapping is possible [ Woodroffe and Streltsov , ]; the reversal in directions arises because the density gradient would be oppositely directed to the other side of the enhancement. The ∼0° azimuthal angle within the enhancement suggests that waves are either propagating in the meridional plane or that there are multiple waves whose out‐of‐meridian components are oppositely directed, giving a net appearance of meridional propagation.…”

Section: Theoretical Backgroundmentioning

confidence: 99%

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Van Allen Probes observations of structured whistler mode activity and coincident electron Landau acceleration inside a remnant plasmaspheric plume

et al. 2017

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We present observations from the Van Allen Probes spacecraft that identify a region of intense whistler mode activity within a large density enhancement outside of the plasmasphere. We speculate that this density enhancement is part of a remnant plasmaspheric plume, with the observed wave being driven by a weakly anisotropic electron injection that drifted into the plume and became nonlinearly unstable to whistler emission. Particle measurements indicate that a significant fraction of thermal (<100 eV) electrons within the plume were subject to Landau acceleration by these waves, an effect that is naturally explained by whistler emission within a gradient and high‐density ducting inside a density enhancement.

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“…It is ultimately possible for any wave normal angle in the range − θ G < θ < θ G (where

θ_{G} = \overset{- 1}{\cos} ω / 2 Ω

Section: Theoretical Backgroundmentioning

confidence: 97%

Section: Theoretical Backgroundmentioning

confidence: 99%

Section: Theoretical Backgroundmentioning

confidence: 99%

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Van Allen Probes observations of structured whistler mode activity and coincident electron Landau acceleration inside a remnant plasmaspheric plume

et al. 2017

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“…Probe A spectral measurements indicate that chorus lower band magnetic field power from 1900 to 2020 UT tends to increase during 5–10 min period enhancements (∼10%) of the plasma density, as measured from EFW antenna potential. It is unclear whether these enhancements help guide the propagation of the chorus to higher magnetic latitudes (e.g., Woodroffe and Streltsov, ) or just enhance their growth rate (Li et al, ).…”

Section: Resonance Location and Mechanismmentioning

confidence: 99%

Observations Directly Linking Relativistic Electron Microbursts to Whistler Mode Chorus: Van Allen Probes and FIREBIRD II

Breneman

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et al. 2017

Geophysical Research Letters

110

157

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We present observations that provide the strongest evidence yet that discrete whistler mode chorus packets cause relativistic electron microbursts. On 20 January 2016 near 1944 UT the low Earth orbiting CubeSat Focused Investigations of Relativistic Electron Bursts: Intensity, Range, and Dynamics (FIREBIRD II) observed energetic microbursts (near L = 5.6 and MLT = 10.5) from its lower limit of 220 keV, to 1 MeV. In the outer radiation belt and magnetically conjugate, Van Allen Probe A observed rising‐tone, lower band chorus waves with durations and cadences similar to the microbursts. No other waves were observed. This is the first time that chorus and microbursts have been simultaneously observed with a separation smaller than a chorus packet. A majority of the microbursts do not have the energy dispersion expected for trapped electrons bouncing between mirror points. This confirms that the electrons are rapidly (nonlinearly) scattered into the loss cone by a coherent interaction with the large amplitude (up to ∼900 pT) chorus. Comparison of observed time‐averaged microburst flux and estimated total electron drift shell content at L = 5.6 indicate that microbursts may represent a significant source of energetic electron loss in the outer radiation belt.

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“…The electron magnetohydrodynamic model was used to calculate the natural VLF waves' distributions in several ducts with transverse sizes around 10 km produced above the HAARP heater. The interaction of VLF whistlers with a periodic system of field‐aligned density irregularities in the ionospheric E layer was also investigated (Woodroffe & Streltsov, ). In both latter cases, irregularities with transverse sizes larger than a few kilometers were considered.…”

Section: Introductionmentioning

confidence: 99%

Whistler Waves' Propagation in Plasmas With Systems of Small‐Scale Density Irregularities: Numerical Simulations and Theory

et al. 2019

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The propagation of whistler waves in a magnetized plasma containing multiple small-scale (100 m to 1 km) field-aligned irregularities of enhanced electron density is considered analytically and by means of numerical simulations. Such systems of irregularities can develop in the upper ionosphere during the generation of density ducts by high-frequency heating facilities and other types of active experiments. The simulation parameters are close to those of an active experiment where a whistler wave of 18 kHz emitted by a ground-based very low frequency (VLF) transmitter was received onboard the DEMETER satellite at 700 km above the SURA heater. The study reveals a number of remarkable properties of the VLF waves' propagation, including the existence of specific waveguide modes of the small-scale density structures and of a characteristic transverse size d 0 of the irregularities. Irregularities with small density enhancements around 10-20% and transverse sizes larger than d 0 ∼ 1 km can serve as separate waveguides for VLF waves. In their turn, single irregularities narrower than d 0 cannot be considered as individual ducting structures. Numerical simulations show that, for the analysis of the electromagnetic whistlers' propagation, a system of closely spaced irregularities with scales narrower than d 0 can be modeled by an equivalent ducting structure with a smoothed density profile. Such equivalent structure has the same ducting properties for whistlers and can be produced by averaging with a sliding window of a scale about d 0 the original density distribution.

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Whistler interaction with field‐aligned density irregularities in the ionosphere: Refraction, diffraction, and interference

Cited by 12 publications

References 30 publications

Van Allen Probes observations of structured whistler mode activity and coincident electron Landau acceleration inside a remnant plasmaspheric plume

Van Allen Probes observations of structured whistler mode activity and coincident electron Landau acceleration inside a remnant plasmaspheric plume

Observations Directly Linking Relativistic Electron Microbursts to Whistler Mode Chorus: Van Allen Probes and FIREBIRD II

Whistler Waves' Propagation in Plasmas With Systems of Small‐Scale Density Irregularities: Numerical Simulations and Theory

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