Neoclassical Diffusion of Radiation‐Belt Electrons Across Very Low <i>L</i>‐Shells

Cunningham, G.; Loridan, V.; Ripoll, J. F.; Schulz, Michael

doi:10.1002/2017ja024931

Cited by 20 publications

(38 citation statements)

References 42 publications

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“…The <D αα > is several orders of magnitude higher near the South Atlantic Anomaly (SAA) (~longitude = 300°) and at smaller equatorial PAs (PA < 65°), since the altitude of electron's mirror point in these regions is much lower (as illustrated in Li et al, ). These <D αα > results are comparable to previous calculations based on different ionospheric plasma models (e.g., Selesnick, , that used the global core plasma model [Gallagher et al, ] and Cunningham et al, , that used the IRI 2007 model [Bilitza & Reinisch, ]). The bounce‐averaged energy loss rates of 304‐keV electrons at L = 1.25 calculated based on equation are shown in Figures g–i.…”

Section: Model Descriptionsupporting

confidence: 86%

“…As in the work of Cunningham et al (), we use the NRLMSISE‐00 model (Picone et al, ) for the number densities of neutral H, He, N, N 2 , O, O 2 , and Ar as a function of altitude, latitude, and the F 10.7 index, and we sample the model output at each point along the magnetic field line at a given location, date, and time using a fixed value of F 10.7 = 70 and Ap = 4. For charged species, we use the H + , He + , O + , NO + , and O 2 + output of the IRI 2012 (Bilitza et al, ).…”

Section: Model Descriptionmentioning

confidence: 99%

“…The other boundary condition is

\frac{\partial J}{\partial α_{eq}} = 0

at α eq = 90° for each ϕ . The

- \frac{\partial}{\partial E} ()(, J \frac{dE}{dt})

term represents the energy loss effect and is treated as a 1‐D advection term (Cunningham et al, ). The energy losses of quasi‐trapped and trapped electrons are solved separately in the drift‐collision‐source model using the energy spectrum of quasi‐trapped and trapped electrons from DEMETER observations (Figures j–l) updated every 30 days, which is a sufficiently high frequency to capture the changes visible in Figures j–l.…”

Section: Model Descriptionmentioning

confidence: 99%

“…Here we will use the term “collisions” to refer to the combined effects of PA scattering due to Coulomb collisions and Coulomb drag. The lifetime of ~500‐keV electrons at L < 1.2 (e.g., Cunningham et al, ; Imhof et al, ) and of 304‐keV electrons at L < 1.4 (e.g., Selesnick, ) calculated from satellite observations is much longer than theoretical estimates from atmospheric collisions, indicating that additional sources exist. Inward radial diffusion of electrons from higher L has been proposed as an additional source (e.g., Selesnick, et al, , suggested inward diffusion as a source of electrons up to L = 1.3), although it was noted quite earlier that the radial diffusion coefficient (inferred from satellite observations) in this scenario shows a decreasing trend as L values increase (at L = 1.15–1.21 from Newkirk & Walt, ), while radial diffusion calculated directly from theory is generally stronger at larger L (Fälthammar, ).…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

On Energetic Electron Dynamics During Geomagnetic Quiet Times in Earth's Inner Radiation Belt due to Atmospheric Collisional Loss and CRAND as a Source

Xiang

Temerin

et al. 2020

JGR Space Physics

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To investigate the role of atmospheric collisions and cosmic ray albedo neutron decay (CRAND) in the dynamics of energetic electrons in the Earth's inner radiation belt during geomagnetic quiet times, a drift‐collision‐source model that includes azimuthal drift, pitch angle diffusion from elastic collision, energy loss from inelastic collision, and a CRAND source is developed. In the model, the bounce‐averaged pitch angle diffusion coefficients and energy loss rates are calculated based on scattering of electrons with neutrals given by the NRLMSISE‐00 model and with ions and electrons given by International Reference Ionosphere (IRI) 2012 model. The electron source rate from CRAND follows the recently developed drift‐source model in Xiang et al. (2019). For 304‐keV quasi‐trapped electrons at L = 1.25, simulation results with CRAND show good agreement with Detection of Electro‐Magnetic Emissions Transmitted from Earthquake Regions satellite observations, confirming that CRAND is the main source for these quasi‐trapped electrons, in contrast to the previous understanding that these quasi‐trapped electrons were formed by wide‐angle scattering of the trapped populations. For trapped electrons, 153, 304, and 509 keV at L < 1.3, the simulation results with only azimuthal drift and atmospheric collisions show a much quicker decrease than observations, while simulation results including a CRAND source are generally comparable to the observations, suggesting that CRAND is an important source of trapped hundreds of kiloelectron‐volt electrons at L < 1.3 during quiet times and provides a baseline for the electron flux even during active times as well. Furthermore, these results suggest that actual radial diffusion rates in the inner belt are lower than previous estimates in which CRAND contributions were not considered.

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Section: Model Descriptionsupporting

confidence: 86%

Section: Model Descriptionmentioning

confidence: 99%

“…The other boundary condition is

\frac{\partial J}{\partial α_{eq}} = 0

at α eq = 90° for each ϕ . The

- \frac{\partial}{\partial E} ()(, J \frac{dE}{dt})

Section: Model Descriptionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

On Energetic Electron Dynamics During Geomagnetic Quiet Times in Earth's Inner Radiation Belt due to Atmospheric Collisional Loss and CRAND as a Source

Xiang

Temerin

et al. 2020

JGR Space Physics

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show abstract

“…They specifically concluded that the model's underestimation when compared to data at high values was due to local acceleration from wave-particle interactions, which was not addressed by their model. In the same perspective, the VERB-3D (e.g., Kim et al, 2011;Shprits et al, 2009;Subbotin et al, 2010) code and the DREAM-3D code (e.g., Cunningham et al, 2018;Tu et al, 2013) are fed with PSD data derived from a variety of magnetic fields (preprocessing step), but they still account for a dipole field when the coordinate transformations are required through the resolution of the Fokker-Planck equation. Nevertheless, the absence of local acceleration in the 1D-RFP model is a strong limitation for storm times.…”

Section: Introductionmentioning

confidence: 99%

On the Use of Different Magnetic Field Models for Simulating the Dynamics of the Outer Radiation Belt Electrons During the October 1990 Storm

Loridan

Ripoll

et al. 2019

JGR Space Physics

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During geomagnetic storms, the magnetic field in the outer belt is known to be significantly distorted by the solar wind, such that the outer belt dynamics can be greatly impacted by the magnetic field topology. In this context, we develop a reduced Fokker‐Planck code that includes the effects related to realistic magnetic field models (by using the existing dedicated LANLGeoMag library) through the steps of preprocessing, postprocessing, and, for the first time, during the computation of the reduced Fokker‐Planck diffusion equation itself. We perform the solutions of the reduced Fokker‐Planck equation in the framework of the geomagnetic storm that occurred from 9 October to 15 October 1990. With the use of Combined Release and Radiation Effects Satellite observations, the magnetic field model is shown to strongly affect the way of conciliating theory with observations (processing steps). More specifically, we explain analytically and numerically why the use of a dipole field can lead to misleading interpretations on the local enhancements (attributed to local acceleration) displayed by the electron distribution function, resulting in inaccurate simulations results at large L‐shells. The consideration of a realistic field does not produce any artificial peaks. With such corrected data sets, a great part of the dynamics can be described by radial transport and is thus better reproduced by the simulations. This crucial importance of the field geometry is further emphasized with the calculation of unidirectional, omnidirectional, and integral electron fluxes, and their accuracy is quantified thanks to dedicated metrics.

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Radiation Belt Radial Diffusion at Earth and Beyond

Lejosne

Kollmann

2020

Space Sci Rev

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Neoclassical Diffusion of Radiation‐Belt Electrons Across Very Low L‐Shells

Cited by 20 publications

References 42 publications

On Energetic Electron Dynamics During Geomagnetic Quiet Times in Earth's Inner Radiation Belt due to Atmospheric Collisional Loss and CRAND as a Source

On Energetic Electron Dynamics During Geomagnetic Quiet Times in Earth's Inner Radiation Belt due to Atmospheric Collisional Loss and CRAND as a Source

On the Use of Different Magnetic Field Models for Simulating the Dynamics of the Outer Radiation Belt Electrons During the October 1990 Storm

Radiation Belt Radial Diffusion at Earth and Beyond

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