Extreme Energy Spectra of Relativistic Electron Flux in the Outer Radiation Belt

Electron diffusion by whistler‐mode chorus waves is one of the key processes controlling the dynamics of relativistic electron fluxes in the Earth's radiation belts. It is responsible for the acceleration of sub‐relativistic electrons injected from the plasma sheet to relativistic energies as well as for their precipitation and loss into the atmosphere. Based on analytical estimates of chorus wave‐driven quasi‐linear electron energy and pitch‐angle diffusion rates, we provide analytical steady‐state solutions to the corresponding Fokker‐Planck equation for the relativistic electron distribution and flux. The impact on these steady‐state solutions of additional electromagnetic ion cyclotron waves, and of ultralow frequency waves are examined. Such steady‐state solutions correspond to hard energy spectra at 1–4 MeV, dangerous for satellite electronics, and represent attractors for the system dynamics in the presence of sufficiently strong driving by continuous injections of 10–300 keV electrons. Therefore, these analytical steady‐state solutions provide a simple means for estimating the most extreme electron energy spectra potentially encountered in the outer radiation belt, despite the great variability of injections and plasma conditions. These analytical steady‐state solutions are compared with numerical simulations based on the full Fokker‐Planck equation and with relativistic electron flux spectra measured by satellites during one extreme event and three strong events of high time‐integrated geomagnetic activity, demonstrating a good agreement.

[1]  D. Vainchtein,et al.  On the Incorporation of Nonlinear Resonant Wave‐Particle Interactions Into Radiation Belt Models , 2022, Journal of Geophysical Research: Space Physics.

[2]  D. Summers,et al.  Analysis of Radiation Belt “Killer” Electron Energy Spectra , 2022, Journal of Geophysical Research: Space Physics.

[3]  J. Bortnik,et al.  Upper Limit of Outer Radiation Belt Electron Acceleration Driven by Whistler‐Mode Chorus Waves , 2022, Geophysical Research Letters.

[4]  Rui Chen,et al.  The Structure and Microstructure of Rising‐Tone Chorus With Frequencies Crossing at f ∼ 0.5 fce , 2022, Journal of Geophysical Research: Space Physics.

[5]  A. Artemyev,et al.  A Climatology of Long‐Duration High 2‐MeV Electron Flux Periods in the Outer Radiation Belt , 2022, Journal of geophysical research. Space physics.

[6]  V. Angelopoulos,et al.  Nonresonant Scattering of Relativistic Electrons by Electromagnetic Ion Cyclotron Waves in Earth's Radiation Belts. , 2022, Physical review letters.

[7]  V. Angelopoulos,et al.  Relativistic Electron Precipitation by EMIC Waves: Importance of Nonlinear Resonant Effects , 2022, Geophysical Research Letters.

[8]  W. Li,et al.  Dependence of Nonlinear Effects on Whistler‐Mode Wave Bandwidth and Amplitude: A Perspective From Diffusion Coefficients , 2022, Journal of Geophysical Research: Space Physics.

[9]  V. Angelopoulos,et al.  Short Chorus Wave Packets: Generation Within Chorus Elements, Statistics, and Consequences on Energetic Electron Precipitation , 2022, Journal of geophysical research. Space physics.

[10]  V. Angelopoulos,et al.  Characteristics of Electron Microburst Precipitation Based on High‐Resolution ELFIN Measurements , 2022, Journal of Geophysical Research: Space Physics.

[11]  V. Angelopoulos,et al.  Superfast precipitation of energetic electrons in the radiation belts of the Earth , 2022, Nature Communications.

[12]  X. Tao,et al.  Electron Dynamics in a Chorus Wave Field Generated From Particle‐In‐Cell Simulations , 2022, Geophysical Research Letters.

[13]  B. Ni,et al.  The 600 keV electron injections in the Earth’s outer radiation belt: A statistical study , 2022, Earth and Planetary Physics.

[14]  R. Horne,et al.  On the Variability of EMIC Waves and the Consequences for the Relativistic Electron Radiation Belt Population , 2021, Journal of Geophysical Research: Space Physics.

[15]  V. Angelopoulos,et al.  Electron Lifetimes and Diffusion Rates Inferred From ELFIN Measurements at Low Altitude: First Results , 2021, Journal of Geophysical Research: Space Physics.

[16]  G. Reeves,et al.  The Magnetic Electron Ion Spectrometer: A Review of On-Orbit Sensor Performance, Data, Operations, and Science , 2021, Space Science Reviews.

[17]  D. Baker,et al.  A Tale of Two Radiation Belts: The Energy‐Dependence of Self‐Limiting Electron Space Radiation , 2021, Geophysical Research Letters.

[18]  M. Hudson,et al.  MHD‐Test Particles Simulations of Moderate CME and CIR‐Driven Geomagnetic Storms at Solar Minimum , 2021, Space Weather.

[19]  V. Angelopoulos,et al.  Fine Structure of Chorus Wave Packets: Comparison Between Observations and Wave Generation Models , 2021, Journal of Geophysical Research: Space Physics.

[20]  A. Neishtadt,et al.  Transitional regime of electron resonant interaction with whistler-mode waves in inhomogeneous space plasma. , 2021, Physical review. E.

[21]  C. Watt,et al.  Electron Diffusion and Advection During Nonlinear Interactions With Whistler‐Mode Waves , 2021, Journal of Geophysical Research: Space Physics.

[22]  Y. Shprits,et al.  Gyroresonant wave-particle interactions with chorus waves during extreme depletions of plasma density in the Van Allen radiation belts , 2021, Science Advances.

[23]  Xinlin Li,et al.  Upper Limit of Electron Fluxes Observed in the Radiation Belts , 2020, Journal of Geophysical Research: Space Physics.

[24]  Yue Chen,et al.  Determining Ionizing Doses in Medium Earth Orbits Using Long-Term GPS Particle Measurements , 2020, 2021 IEEE Aerospace Conference (50100).

[25]  S. Kurita,et al.  Relativistic Electron Microbursts as High‐Energy Tail of Pulsating Aurora Electrons , 2020, Geophysical Research Letters.

[26]  B. Tsurutani,et al.  Statistical Evidence for EMIC Wave Excitation Driven by Substorm Injection and Enhanced Solar Wind Pressure in the Earth's Magnetosphere: Two Different EMIC Wave Sources , 2020, Geophysical Research Letters.

[27]  V. Angelopoulos,et al.  Phase Decoherence Within Intense Chorus Wave Packets Constrains the Efficiency of Nonlinear Resonant Electron Acceleration , 2020, Geophysical Research Letters.

[28]  Y. Shprits,et al.  Local heating of radiation belt electrons to ultra-relativistic energies , 2020, Nature Communications.

[29]  Lunjin Chen,et al.  Modeling of Bouncing Electron Microbursts Induced by Ducted Chorus Waves , 2020, Geophysical Research Letters.

[30]  M. Hudson,et al.  The Role of Hiss, Chorus, and EMIC Waves in the Modeling of the Dynamics of the Multi‐MeV Radiation Belt Electrons , 2020, Journal of Geophysical Research: Space Physics.

[31]  V. Angelopoulos,et al.  Rapid Frequency Variations Within Intense Chorus Wave Packets , 2020, Geophysical Research Letters.

[32]  R. Boynton,et al.  Outer Radiation Belt Electron Lifetime Model Based on Combined Van Allen Probes and Cluster VLF Measurements , 2020, Journal of Geophysical Research: Space Physics.

[33]  J. Bonnell,et al.  Lifetimes of Relativistic Electrons as Determined From Plasmaspheric Hiss Scattering Rates Statistics: Effects of ωpe/Ωce and Wave Frequency Dependence on Geomagnetic Activity , 2020, Geophysical Research Letters.

[34]  S. Glauert,et al.  Particle‐in‐Cell Experiments Examine Electron Diffusion by Whistler‐Mode Waves: 2. Quasi‐Linear and Nonlinear Dynamics , 2020, Journal of Geophysical Research: Space Physics.

[35]  R. Wirz,et al.  The ELFIN Mission , 2020, Space science reviews.

[36]  J. Bortnik,et al.  On the Confinement of Ultrarelativistic Electron Remnant Belts to Low L Shells , 2020, Journal of Geophysical Research: Space Physics.

[37]  T. O'Brien,et al.  Empirically Estimated Electron Lifetimes in the Earth's Radiation Belts: Van Allen Probe Observations , 2020, Geophysical research letters.

[38]  A. Degeling,et al.  Rapid Outer Radiation Belt Flux Dropouts and Fast Acceleration During the March 2015 and 2013 Storms: The Role of Ultra‐Low Frequency Wave Transport From a Dynamic Outer Boundary , 2020, Journal of Geophysical Research: Space Physics.

[39]  W. Li,et al.  Earth's Van Allen Radiation Belts: From Discovery to the Van Allen Probes Era , 2019, Journal of Geophysical Research: Space Physics.

[40]  A. Degeling,et al.  Rapid Outer Radiation Belt Flux Dropouts and Fast Acceleration during the March 2015 and 2013 Storms: Role of ULF Wave Transport from a Dynamic Outer Boundary , 2019 .

[41]  V. Angelopoulos,et al.  Nonlinear Electron Interaction With Intense Chorus Waves: Statistics of Occurrence Rates , 2019, Geophysical Research Letters.

[42]  V. Angelopoulos,et al.  Utilizing the Heliophysics/Geospace System Observatory to Understand Particle Injections: Their Scale Sizes and Propagation Directions , 2019, Journal of Geophysical Research: Space Physics.

[43]  R. Horne,et al.  Effects of VLF Transmitter Waves on the Inner Belt and Slot Region , 2019, Journal of Geophysical Research: Space Physics.

[44]  J. Bonnell,et al.  Time Scales for Electron Quasi‐linear Diffusion by Lower‐Band Chorus Waves: The Effects of ωpe/Ωce Dependence on Geomagnetic Activity , 2019, Geophysical Research Letters.

[45]  D. Mourenas,et al.  Impact of Significant Time‐Integrated Geomagnetic Activity on 2‐MeV Electron Flux , 2019, Journal of Geophysical Research: Space Physics.

[46]  M. Lockwood,et al.  A homogeneous aa index: 1. Secular variation , 2018, 1811.09810.

[47]  R. Horne,et al.  A 30‐Year Simulation of the Outer Electron Radiation Belt , 2018, Space Weather.

[48]  R. Horne,et al.  Radiation Effects on Satellites During Extreme Space Weather Events , 2018, Space Weather.

[49]  V. Angelopoulos,et al.  Electron Flux Enhancements at L = 4.2 Observed by Global Positioning System Satellites: Relationship With Solar Wind and Geomagnetic Activity , 2018, Journal of Geophysical Research: Space Physics.

[50]  V. Angelopoulos,et al.  Properties of Intense Field‐Aligned Lower‐Band Chorus Waves: Implications for Nonlinear Wave‐Particle Interactions , 2018, Journal of Geophysical Research: Space Physics.

[51]  D. Baker,et al.  What Causes Radiation Belt Enhancements: A Survey of the Van Allen Probes Era , 2018, Geophysical Research Letters.

[52]  Y. Omura,et al.  Nonlinear Dynamics of Radiation Belt Electrons Interacting With Chorus Emissions Localized in Longitude , 2018, Journal of Geophysical Research: Space Physics.

[53]  A. Neishtadt,et al.  Electron Nonlinear Resonant Interaction With Short and Intense Parallel Chorus Wave Packets , 2018, Journal of Geophysical Research: Space Physics.

[54]  D. Baker,et al.  The Global Statistical Response of the Outer Radiation Belt During Geomagnetic Storms , 2018 .

[55]  D. Baker,et al.  Quantitative Evaluation of Radial Diffusion and Local Acceleration Processes During GEM Challenge Events , 2018 .

[56]  J. Bonnell,et al.  Synthetic Empirical Chorus Wave Model From Combined Van Allen Probes and Cluster Statistics , 2018 .

[57]  R. Boynton,et al.  Electron Flux Dropouts at L ∼ 4.2 From Global Positioning System Satellites: Occurrences, Magnitudes, and Main Driving Factors , 2017 .

[58]  Yang Wang,et al.  The effects of magnetospheric processes on relativistic electron dynamics in the Earth's outer radiation belt , 2017 .

[59]  V. Angelopoulos,et al.  Contemporaneous EMIC and whistler mode waves: Observations and consequences for MeV electron loss , 2017 .

[60]  W. Li,et al.  Scaling laws for the inner structure of the radiation belts , 2017 .

[61]  J. Bonnell,et al.  Chorus whistler wave source scales as determined from multipoint Van Allen Probe measurements , 2017 .

[62]  V. Angelopoulos,et al.  Statistical distribution of EMIC wave spectra: Observations from Van Allen Probes , 2016 .

[63]  V. Angelopoulos,et al.  Energy limits of electron acceleration in the plasma sheet during substorms: A case study with the Magnetospheric Multiscale (MMS) mission , 2016 .

[64]  W. Li,et al.  Fast dropouts of multi‐MeV electrons due to combined effects of EMIC and whistler mode waves , 2016 .

[65]  D. Baker,et al.  The Global Positioning System constellation as a space weather monitor: Comparison of electron measurements with Van Allen Probes data , 2016 .

[66]  H. Spence,et al.  Dipolarizing flux bundles in the cis‐geosynchronous magnetosphere: Relationship between electric fields and energetic particle injections , 2015 .

[67]  V. Krasnoselskikh,et al.  Nonlinear local parallel acceleration of electrons through Landau trapping by oblique whistler mode waves in the outer radiation belt , 2015 .

[68]  V. Krasnoselskikh,et al.  Empirical model of lower band chorus wave distribution in the outer radiation belt , 2015 .

[69]  Chen Zhou,et al.  Resonant scattering of outer zone relativistic electrons by multiband EMIC waves and resultant electron loss time scales , 2015 .

[70]  F. Mozer,et al.  Stability of relativistic electron trapping by strong whistler or electromagnetic ion cyclotron waves , 2015 .

[71]  A. Runov,et al.  Average thermodynamic and spectral properties of plasma in and around dipolarizing flux bundles , 2015 .

[72]  Q. Lu,et al.  The effect of different solar wind parameters upon significant relativistic electron flux dropouts in the magnetosphere , 2015 .

[73]  G. Reeves,et al.  Energetic electron injections deep into the inner magnetosphere associated with substorm activity , 2015 .

[74]  L. Lanzerotti,et al.  Spatial structure and temporal evolution of energetic particle injections in the inner magnetosphere during the 14 July 2013 substorm event , 2015, 1606.02656.

[75]  W. Kurth,et al.  Electron densities inferred from plasma wave spectra obtained by the Waves instrument on Van Allen Probes , 2015, Journal of geophysical research. Space physics.

[76]  Harlan E. Spence,et al.  Energetic, relativistic, and ultrarelativistic electrons: Comparison of long‐term VERB code simulations with Van Allen Probes measurements , 2014 .

[77]  W. Li,et al.  Approximate analytical solutions for the trapped electron distribution due to quasi‐linear diffusion by whistler mode waves , 2014 .

[78]  D. Baker,et al.  Quantifying the relative contributions of substorm injections and chorus waves to the rapid outward extension of electron radiation belt , 2014 .

[79]  R. Horne,et al.  Electron losses from the radiation belts caused by EMIC waves , 2014 .

[80]  Maria Spasojevic,et al.  Statistical analysis of ground‐based chorus observations during geomagnetic storms , 2014 .

[81]  D. Summers,et al.  Limiting energy spectrum of an electron radiation belt , 2014 .

[82]  R. Boynton,et al.  Statistical analysis of electron lifetimes at GEO: Comparisons with chorus‐driven losses , 2014 .

[83]  J. Birn,et al.  Energetic electrons in dipolarization events: Spatial properties and anisotropy , 2014 .

[84]  V. Angelopoulos,et al.  Statistical characteristics of particle injections throughout the equatorial magnetotail , 2014 .

[85]  M. Spasojević,et al.  Electromagnetic ion cyclotron wave modeling during the geospace environment modeling challenge event , 2014 .

[86]  V. Krasnoselskikh,et al.  Consequences of geomagnetic activity on energization and loss of radiation belt electrons by oblique chorus waves , 2014 .

[87]  Harlan E. Spence,et al.  Effect of EMIC waves on relativistic and ultrarelativistic electron populations: Ground‐based and Van Allen Probes observations , 2014 .

[88]  D. Baker,et al.  Event‐specific chorus wave and electron seed population models in DREAM3D using the Van Allen Probes , 2014 .

[89]  I. Mann,et al.  Analytic expressions for ULF wave radiation belt radial diffusion coefficients , 2014, Journal of geophysical research. Space physics.

[90]  J. B. Blake,et al.  Rapid local acceleration of relativistic radiation-belt electrons by magnetospheric chorus , 2013, Nature.

[91]  David G. Sibeck,et al.  Science Objectives and Rationale for the Radiation Belt Storm Probes Mission , 2012, Space Science Reviews.

[92]  J. B. Blake,et al.  Science Goals and Overview of the Radiation Belt Storm Probes (RBSP) Energetic Particle, Composition, and Thermal Plasma (ECT) Suite on NASA’s Van Allen Probes Mission , 2013, Space Science Reviews.

[93]  L. Zelenyi,et al.  Storm‐induced energization of radiation belt electrons: Effect of wave obliquity , 2013 .

[94]  J. Bortnik,et al.  The importance of amplitude modulation in nonlinear interactions between electrons and large amplitude whistler waves , 2013 .

[95]  D. Crawford,et al.  The Electric and Magnetic Field Instrument Suite and Integrated Science (EMFISIS) on RBSP , 2013 .

[96]  V. Krasnoselskikh,et al.  Parametric validations of analytical lifetime estimates for radiation belt electron diffusion by whistler waves , 2013 .

[97]  V. Angelopoulos,et al.  On the storm‐time evolution of relativistic electron phase space density in Earth's outer radiation belt , 2013 .

[98]  J. Bortnik,et al.  Aspects of Nonlinear Wave-Particle Interactions , 2013 .

[99]  J. Bortnik,et al.  Modeling the wave normal distribution of chorus waves , 2013 .

[100]  S. Billings,et al.  Time scaling of the electron flux increase at GEO: The local energy diffusion model vs observations , 2012 .

[101]  J. Bortnik,et al.  Comparison of bounce‐averaged quasi‐linear diffusion coefficients for parallel propagating whistler mode waves with test particle simulations , 2012 .

[102]  V. Krasnoselskikh,et al.  Acceleration of radiation belts electrons by oblique chorus waves , 2012 .

[103]  P. Ozhogin,et al.  Field-aligned distribution of the plasmaspheric electron density: An empirical model derived from the IMAGE RPI measurements , 2012 .

[104]  J. Ripoll,et al.  Timescales for electron quasi‐linear diffusion by parallel and oblique lower‐band chorus waves , 2012 .

[105]  Y. Shprits,et al.  Radial distributions of equatorial phase space density for outer radiation belt electrons , 2012 .

[106]  D. Baker,et al.  Particle Acceleration in the Magnetotail and Aurora , 2012 .

[107]  J. Ripoll,et al.  Analytical estimates of quasi-linear diffusion coefficients and electron lifetimes in the inner radiation belt , 2012 .

[108]  R. Kataoka,et al.  Solar cycle variations of outer radiation belt and its relationship to solar wind structure dependences , 2011 .

[109]  J. Bortnik,et al.  Nonlinear interactions between relativistic radiation belt electrons and oblique whistler mode waves , 2010 .

[110]  I. J. Rae,et al.  Conjugate ground and multisatellite observations of compression-related EMIC Pc1 waves and associated proton precipitation , 2010 .

[111]  V. Angelopoulos,et al.  THEMIS analysis of observed equatorial electron distributions responsible for the chorus excitation , 2010 .

[112]  J. Albert Diffusion by one wave and by many waves , 2010 .

[113]  J. Albert The coupling of quasi-linear pitch angle and energy diffusion , 2009 .

[114]  Y. Shprits,et al.  Estimates of lifetimes against pitch angle diffusion , 2009 .

[115]  K. Orlova,et al.  Dependence of the relativistic electron energy spectra during the magnetic storm recovery phase on the acceleration and loss rates , 2009 .

[116]  Y. Omura,et al.  Rapid energization of radiation belt electrons by nonlinear wave trapping , 2008 .

[117]  A. Degeling,et al.  Drift resonant generation of peaked relativistic electron distributions by Pc 5 ULF waves , 2008 .

[118]  Richard M. Thorne,et al.  Dynamic evolution of energetic outer zone electrons due to wave‐particle interactions during storms , 2007 .

[119]  Geoffrey D. Reeves,et al.  The energization of relativistic electrons in the outer Van Allen radiation belt , 2007 .

[120]  Y. Omura,et al.  Relativistic Turning Acceleration of Resonant Electrons by Coherent Whistler-Mode Waves in a Dipole Magnetic Field(RECENT RESEARCH ACTIVITIES) , 2007 .

[121]  D. Nunn,et al.  Electron acceleration in the magnetosphere by whistler-mode waves of varying frequency , 2006 .

[122]  Y. Kasahara,et al.  Corotating solar wind streams and recurrent geomagnetic activity: A review , 2006 .

[123]  J. Borovsky,et al.  Differences between CME‐driven storms and CIR‐driven storms , 2006 .

[124]  Jay M. Albert,et al.  Multidimensional quasi‐linear diffusion of radiation belt electrons , 2005 .

[125]  Richard M. Thorne,et al.  Timescale for radiation belt electron acceleration by whistler mode chorus waves , 2005 .

[126]  N. Tsyganenko,et al.  Modeling the dynamics of the inner magnetosphere during strong geomagnetic storms , 2005 .

[127]  M. Kivelson,et al.  Relativistic electrons in the outer radiation belt: Differentiating between acceleration mechanisms , 2004 .

[128]  M. Parrot,et al.  Spatio-temporal structure of storm-time chorus , 2003 .

[129]  R. Horne,et al.  Evidence for chorus‐driven electron acceleration to relativistic energies from a survey of geomagnetically disturbed periods , 2003 .

[130]  R. Horne,et al.  Relativistic electron acceleration and precipitation during resonant interactions with whistler‐mode chorus , 2003 .

[131]  Richard M. Thorne,et al.  Relativistic electron pitch-angle scattering by electromagnetic ion cyclotron waves during geomagnetic storms , 2003 .

[132]  Mark B. Moldwin,et al.  Empirical plasmapause models from magnetic indices , 2003 .

[133]  Ondrej Santolik,et al.  Singular value decomposition methods for wave propagation analysis , 2003 .

[134]  R. Horne,et al.  Model of the energization of outer‐zone electrons by whistler‐mode chorus during the October 9, 1990 geomagnetic storm , 2002 .

[135]  Richard M. Thorne,et al.  Outer zone relativistic electron acceleration associated with substorm‐enhanced whistler mode chorus , 2002 .

[136]  Mark B. Moldwin,et al.  An empirical plasmasphere and trough density model: CRRES observations , 2001 .

[137]  R. Horne,et al.  The temporal evolution of electron distributions and associated wave activity following substorm injections in the inner magnetosphere , 2000 .

[138]  D. Summers,et al.  A model for generating relativistic electrons in the Earth's inner magnetosphere based on gyroresonant wave‐particle interactions , 1999, physics/9910020.

[139]  R. Thorne,et al.  Relativistic theory of wave‐particle resonant diffusion with application to electron acceleration in the magnetosphere , 1998 .

[140]  Richard M. Thorne,et al.  Potential waves for relativistic electron scattering and stochastic acceleration during magnetic storms , 1998 .

[141]  J. Birn,et al.  Substorm electron injections: Geosynchronous observations and test particle simulations , 1998 .

[142]  V. Jordanova,et al.  Modeling of the contribution of electromagnetic ion cyclotron (EMIC) waves to stormtime ring current erosion , 2013 .

[143]  A. Chan,et al.  Fully adiabatic changes in storm time relativistic electron fluxes , 1997 .

[144]  J. Birn,et al.  Characteristic plasma properties during dispersionless substorm injections at geosynchronous orbit , 1997 .

[145]  Barry H. Mauk,et al.  Introduction to Geomagnetically Trapped Radiation , 1996 .

[146]  James I. Vette,et al.  The AE-8 trapped electron model environment , 1991 .

[147]  Lou‐Chuang Lee,et al.  Pc1 wave generation by sudden impulses , 1983 .

[148]  A. Lichtenberg,et al.  Regular and Stochastic Motion , 1982 .

[149]  P. Mayaud,et al.  Derivation, Meaning, and Use of Geomagnetic Indices , 1980 .

[150]  D. Shklyar,et al.  Partcle precipitation caused by a single whistler-mode wave injected into the magnetosphere , 1977 .

[151]  L. Lyons,et al.  Pitch angle and energy diffusion coefficients from resonant interactions with ion–cyclotron and whistler waves , 1974, Journal of Plasma Physics.

[152]  V. Karpman Nonlinear effects in the ELF waves propagating along the magnetic field in the magnetosphere , 1974 .

[153]  B. Tsurutani,et al.  Postmidnight chorus: A substorm phenomenon , 1974 .

[154]  J. Cornwall,et al.  TURBULENT LOSS OF RING-CURRENT PROTONS. , 1970 .

[155]  R. L. Arnoldy,et al.  PARTICLE SUBSTORMS OBSERVED AT THE GEOSTATIONARY ORBIT. , 1969 .

[156]  G. Haerendel DIFFUSION THEORY OF TRAPPED PARTICLES AND THE OBSERVED PROTON DISTRIBUTION. , 1968 .

[157]  Charles F. Kennel,et al.  LIMIT ON STABLY TRAPPED PARTICLE FLUXES , 1966 .

[158]  A. Andronov,et al.  KINETIC INSTABILITY OF THE EARTH'S OUTER RADIATION BELT , 1964 .

[159]  N. Herlofson,et al.  Particle Diffusion in the Radiation Belts , 1962 .

[160]  R. Fowler FURTHER STUDIES OF EMDEN'S AND SIMILAR DIFFERENTIAL EQUATIONS , 1931 .