Sensitivity of EMIC Wave‐Driven Scattering Loss of Ring Current Protons to Wave Normal Angle Distribution

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Scattering by plasmaspheric hiss is responsible for the newly reported reversed energy spectra with abundant high‐energy but fewer low‐energy electrons between hundreds of kiloelectronvolts and ~2 MeV in the inner magnetosphere. To deepen our understanding of the contributions of plasmaspheric hiss to the formation of reversed electron energy spectrum, we conduct a detailed theoretical parametric analysis through numerical simulations to explore the sensitivity of hiss‐induced reversed electron energy spectrum to ambient magnetic field, plasma density, and hiss wave distribution properties. Given L‐shell, variations of ambient plasma density and wave frequency spectrum contribute importantly to the formation of reversed electron energy spectrum, while variations of background magnetic field (which usually shows small changes in the plasmasphere) and wave normal angle distribution play a less effective role. Our study suggests that the reversed electron energy spectrum has important implications for unveiling the sophisticated energy‐dependent nature of wave‐particle interactions and energetic particle dynamics in geospace.

Section: Sensitivity Analysismentioning

confidence: 98%

Parametric Sensitivity of the Formation of Reversed Electron Energy Spectrum Caused by Plasmaspheric Hiss

Huang

Zhang

et al. 2019

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“…The polarization reversal at the crossover frequency will significantly modify the dispersive properties of EMIC waves at high latitudes and may subsequently affect the EMIC wave‐driven scattering of magnetospheric particles. However, in the calculations of quasi‐linear bounce‐averaged particle diffusion coefficients, previous studies commonly assumed that EMIC waves are purely left‐hand polarized for both strictly parallel propagating (e.g., Ni et al, 2018; Summers & Thorne, 2003; Ukhorskiy et al, 2010; Usanova et al, 2014; Xiao et al, 2012) and obliquely propagating events (e.g., Albert, 2003; Cao et al, 2016, 2019; Capannolo et al, 2019; Glauert & Horne, 2005; He et al, 2016; Ni et al, 2015; Uzbekov et al, 2016). Some recent studies also assumed that EMIC waves are confined to below the geomagnetic latitudes where the polarization reversal can occur (e.g., Ma et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Effects of Polarization Reversal on the Pitch Angle Scattering of Radiation Belt Electrons and Ring Current Protons by EMIC Waves

Cao

Summers

et al. 2020

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In this study, we investigate the effects of polarization reversal of electromagnetic ion cyclotron (EMIC) waves at the crossover frequencies on computations of bounce‐averaged pitch angle diffusion coefficients of radiation belt electrons and ring current protons. We find that inclusion of polarization reversal can cause significant changes of H+ band‐induced particle diffusion coefficients, while scattering by the He+ band is almost unaffected. Our results show that the pure L‐mode approach, which has been widely implemented in previous studies, tends to underestimate the diffusion coefficients of ultrarelativistic (>4 MeV) electrons and overestimate those of 10–50 and >100 keV protons caused by H+ band EMIC waves. Especially for >100 keV protons, the differences in diffusion coefficients can be larger by an order of magnitude. We confirm that the polarization reversal can contribute importantly to the scattering loss of radiation belt electrons and ring current protons by H+ band EMIC waves.

“…Multiple satellite observations have indicated the heating of helium (He + ) and proton (H + ) ions at thermal energies of several hundred eV by EMIC waves and magnetosonic waves in the magnetosphere (Anderson & Fuselier, ; Fuselier & Anderson, ; Mauk et al, ; Mouikis et al, ; Roux et al, ; Young et al, ; Yuan et al, ; Zhang et al, ). Resonant interaction analyses, using both theory and numerical modeling, have suggested the possible ion scattering and acceleration at ring current energies or thermal energies associated with EMIC waves and magnetosonic waves, because the Doppler‐shifted wave frequency could be close to the ion gyrofrequency or its harmonics (Bortnik et al, ; Cao et al, , ; Fu et al, ; Gendrin & Roux, ; Isenberg, ). In addition, the ray‐tracing simulations have indicated that EMIC waves could be absorbed by the thermal ions as their wave normal angles become oblique on their propagation path (Horne & Thorne, ; Thorne & Horne, ), and that radially propagating magnetosonic waves could heat the thermal protons (Horne et al, ).…”

Section: Introductionmentioning

confidence: 99%

Ion Heating by Electromagnetic Ion Cyclotron Waves and Magnetosonic Waves in the Earth's Inner Magnetosphere

Yue

et al. 2019

Electromagnetic ion cyclotron (EMIC) waves and magnetosonic waves are commonly observed in the Earth's magnetosphere associated with enhanced ring current activity. Using wave and ion measurements from the Van Allen Probes, we identify clear correlations between the hydrogen‐ and helium‐band EMIC waves with the enhancement of trapped helium and oxygen ion fluxes, respectively. We calculate the diffusion coefficients of different ion species using quasi‐linear theory to understand the effects of resonant scattering by EMIC waves. Our calculations indicate that EMIC waves can cause pitch angle scattering loss of several keV to hundreds of keV ions, and heating of tens of eV to several keV helium and oxygen ions by hydrogen‐ and helium‐band EMIC waves, respectively. Moreover, we found that magnetosonic waves can cause the resonant heating of thermal protons. Our study indicates the importance of energy transfer from the EMIC and magnetosonic waves to ions with different species at thermal energies.