Investigating Whistler‐Mode Wave Intensity Along Field Lines Using Electron Precipitation Measurements

Electron fluxes in Earth's radiation belts are significantly affected by their resonant interaction with whistler‐mode waves. This wave‐particle interaction often occurs via first cyclotron resonance and, when intense and nonlinear, can accelerate subrelativistic electrons to relativistic energ...

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Bibliographic Details
Published in:Journal of geophysical research. Space physics 2023-08, Vol.128 (8), p.n/a
Main Authors: Tsai, Ethan, Artemyev, Anton, Angelopoulos, Vassilis, Zhang, Xiao‐Jia
Format: Article
Language:English
Subjects:
Atmospheric models
Cubesat
Cyclotron resonance
Earth
Earth magnetosphere
Electron flux
Electron precipitation
ELFIN
Empirical models
Energy spectra
Equator
Interaction models
Jupiter
Latitude
latitudinal distribution of wave power
Modelling
nonlinear wave‐particle interaction
Particle interactions
Plasma density
Plasma waves
Precipitation measurements
Radiation
Radiation belt electrons
radiation belt modeling
Radiation belts
Relativistic effects
relativistic electron precipitation
Resonant interactions
Spacecraft
Spatial distribution
Statistical models
Wave measurement
Wave models
Wave power
Waveforms
whistler wave
Whistlers
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Summary:Electron fluxes in Earth's radiation belts are significantly affected by their resonant interaction with whistler‐mode waves. This wave‐particle interaction often occurs via first cyclotron resonance and, when intense and nonlinear, can accelerate subrelativistic electrons to relativistic energies while also scattering them into the atmospheric loss cone. Here, we model Electron Losses and Fields INvestgation’s (ELFIN) low‐altitude satellite measurements of precipitating electron spectra with a wave‐electron interaction model to infer the profiles of whistler‐mode intensity along magnetic latitude assuming realistic waveforms and statistical models of plasma density. We then compare these profiles with a wave power spatial distribution along field lines from an empirical model. We find that this empirical model is consistent with observations of subrelativistic (200 keV) electron precipitation events at all MLTs, especially on the nightside. This may be due to the sparse coverage of wave measurements at mid‐to‐high latitudes which causes statistically averaged wave power to be likely underestimated in current empirical wave models. As a result, this discrepancy suggests that intense waves likely do propagate to higher latitudes, although further investigation is required to quantify how well this high‐latitude population can account for the observed relativistic electron precipitation. Plain Language Summary Whistler‐mode waves, the most prevalent type of plasma wave in Earth's magnetosphere, often interact with electrons by resonating with them, causing them to be accelerated and lost into Earth's atmosphere (in other words, precipitated). These waves are generated at the equator and typically stay constrained to within 20° in latitude; however, they can sometimes propagate to greater than 30° where they can accelerate electrons to relativistic energies. It is difficult to quantify how large of a contribution these mid‐to‐high‐latitude waves have on radiation belt electrons due to a lack of off‐equatorial spacecraft wave measurements. However, previous studies have shown that the energy spectra of precipitating electron fluxes may be used to infer the latitudinal extent of whistler‐mode waves. We therefore compare measurements of relativistic precipitation from NASA's Electron Losses and Fields INvestgation (ELFIN) mission (a pair of CubeSats built and operated by UCLA)
ISSN:2169-9380
2169-9402
DOI:10.1029/2023JA031578