Upper Limit on Outer Radiation Belt Electron Flux Based on Dynamical Equilibrium

Mourenas, D.; Artemyev, А. V.; Zhang, Xiaojia; Angelopoulos, Vassilis

doi:10.1029/2023ja031676

Cited by 2 publications

(23 citation statements)

References 139 publications

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“…To estimate the wave power gain G(t) and its relationship to the equatorial trapped electron flux J trap (α 0 = 90°) based on ELFIN CubeSat measurements, we need to calculate J prec1 /J trap and J prec2 /J trap at different successive times t i during each storm. Assuming a quasi-equilibrium pitch-angle electron distribution at 0.08 0.6 MeV (as justified by previous works, see Mourenas et al, 2021;Shane et al, 2023), quasi-linear theory (Kennel & Petschek, 1966; shows that the average precipitating to trapped flux ratio measured at ELFIN CubeSats can be approximately written as (Mourenas et al, 2023), equivalent to:…”

Section: 1029/2023ja032193mentioning

confidence: 70%

“…This energy range, ∼0.08 0.6 MeV, corresponds to the main population of cyclotron resonant electrons with equatorial pitch-angles α 0 > 60°efficiently generating parallel chorus waves of mean normalized frequency ω/Ω ce0 ≃ 0.2 0.25 (Agapitov et al, 2018;W. Li et al, 2016) for a typical plasma frequency to gyrofrequency ratio Ω pe0 /Ω ce0 ≃ 4.5 near L ∼ 5 during disturbed periods (Agapitov et al, 2019;Mourenas et al, 2023;.…”

Section: Analysis Of Electron Fluxesmentioning

confidence: 93%

“…The electron flux pitch-angle anisotropy s for a distribution of the form J trap (α 0 ) = sin 2s α 0 (Summers et al, 2009) for α 0 = 10°-90°(i.e., for most of the electron population providing the free energy for chorus wave growth, see Omura et al, 2008;Tao et al, 2017; can be similarly estimated based on quasilinear theory (Mourenas et al, 2023), giving:…”

Section: 1029/2023ja032193mentioning

confidence: 99%

“…As will appear below, this method requires energy-resolved measurements of trapped electron fluxes J trap at pitch-angles just above the loss cone (for ELFIN data, at α 0 ≃ 1.05 α 0,LC where α 0 and α 0,LC denote the equatorial pitch-angle and loss cone angle, respectively), and energy-resolved data of both precipitating electron fluxes J prec, meas measured above ELFIN within the local bounce loss cone and backscattered (by the atmosphere) electron fluxes J up measured below ELFIN within the local anti-loss-cone (see examples of measured trapped, precipitating and backscattered fluxes in Figure 1 from Mourenas et al, 2023), sufficiently well resolved in pitch-angle, to allow an accurate determination of the average (over local pitch-angles) effective net flux J prec ≃ J prec, meas J up of electrons precipitated by whistler-mode waves within the loss cone (Mourenas et al, 2023). The lowaltitude ELFIN CubeSats precisely provide the needed electron flux data with a good resolution in pitch-angle within the loss cone (Angelopoulos et al, 2020(Angelopoulos et al, , 2023).…”

Section: Generalitiesmentioning

confidence: 99%

“…It is worth noting that, in deriving Equation 6, we made use of normalized z 0 (t i ) and flux values. An advantage of this method, previously used for electromagnetic ion cyclotron (EMIC) waves (Angelopoulos et al, 2023), is that such a normalization leads to a cancellation of all parameters in z 0 that remain approximately constant during the examined time interval, such as the plasma frequency to gyrofrequency ratio or the wave frequency to gyrofrequency ratio (Mourenas et al, 2023). As a result, the wave power gain near the magnetic equator can be inferred from low-altitude measurements alone, without additional plasma or wave measurements in the equatorial and mid-latitude regions where wave generation and electron precipitation take place.…”

Section: Journal Of Geophysical Research: Space Physicsmentioning

confidence: 99%

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Checking Key Assumptions of the Kennel‐Petschek Flux Limit With ELFIN CubeSats

Mourenas,

Artemyev,

Zhang

et al. 2024

JGR Space Physics

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In planetary radiation belts, the Kennel‐Petschek flux limit is expected to set an upper limit on trapped electron fluxes at 80–600 keV in the presence of efficient electron loss through pitch‐angle diffusion by whistler‐mode chorus waves generated around the magnetic equator by the same 80–600 keV electron population. Comparisons with maximum measured fluxes have been relatively successful, but several key assumptions of the Kennel‐Petschek model have not been experimentally tested. The Kennel‐Petschek model notably assumes an exponential growth of chorus waves as the trapped electron flux increases, and a fixed maximum wave power gain of about 3. Here, we describe a method for inferring the near‐equatorial wave power gain using only measurements of trapped, precipitating, and backscattered electron fluxes at low altitude. Next, we make use of Electron Losses and Fields Investigation (ELFIN) CubeSats measurements of such electron fluxes during two moderate geomagnetic storms with sustained electron injections to infer the corresponding chorus wave power gains as a function of time, energy, and equatorial trapped electron flux. We show that wave power increases exponentially with trapped flux, with a wave power gain roughly proportional to the theoretical linear convective gain, and that the maximum inferred gain near the upper flux limit is roughly 10, with a factor of 2 uncertainty. Therefore, two key theoretical underpinnings of the Kennel‐Petschek model are borne out by the present results, although the strong inferred gains should correspond to higher flux limits than in traditional estimates.

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Section: 1029/2023ja032193mentioning

confidence: 70%

Section: Analysis Of Electron Fluxesmentioning

confidence: 93%

Section: 1029/2023ja032193mentioning

confidence: 99%

Section: Generalitiesmentioning

confidence: 99%

Section: Journal Of Geophysical Research: Space Physicsmentioning

confidence: 99%

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Checking Key Assumptions of the Kennel‐Petschek Flux Limit With ELFIN CubeSats

Mourenas,

Artemyev,

Zhang

et al. 2024

JGR Space Physics

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Key Factors Determining Nightside Energetic Electron Losses Driven by Whistler‐Mode Waves

Tsai,

Artemyev,

et al. 2024

JGR Space Physics

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Energetic electron losses by pitch‐angle scattering and precipitation to the atmosphere from the radiation belts are controlled, to a great extent, by resonant wave particle interactions with whistler‐mode waves. The efficacy of such precipitation is primarily modulated by wave intensity, although its relative importance, compared to other wave and plasma parameters, remains unclear. Precipitation spectra from the low‐altitude, polar‐orbiting ELFIN mission have previously been demonstrated to be consistent with energetic precipitation modeling derived from empirical models of field‐aligned wave power across a wide swath of local‐time sectors. However, such modeling could not explain the intense, relativistic electron precipitation observed on the nightside. Therefore, this study aims to additionally consider the contributions of three modifications—wave obliquity, frequency spectrum, and local plasma density—to explain this discrepancy on the nightside. By incorporating these effects into both test particle simulations and quasi‐linear diffusion modeling, we find that realistic implementations of each individual modification result in only slight changes to the electron precipitation spectrum. However, these modifications, when combined, enable more accurate modeling of ELFIN‐observed spectra. In particular, a significant reduction in plasma density enables lower frequency waves, oblique, or even quasi field‐aligned waves to resonate with near ∼1 MeV electrons closer to the equator. We demonstrate that the levels of modification required to accurately reproduce the nightside spectra of whistler‐mode wave‐driven relativistic electron precipitation match empirical expectations and should therefore be included in future radiation belt modeling.

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Upper Limit on Outer Radiation Belt Electron Flux Based on Dynamical Equilibrium

Cited by 2 publications

References 139 publications

Checking Key Assumptions of the Kennel‐Petschek Flux Limit With ELFIN CubeSats

Checking Key Assumptions of the Kennel‐Petschek Flux Limit With ELFIN CubeSats

Key Factors Determining Nightside Energetic Electron Losses Driven by Whistler‐Mode Waves

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