The proton and electron radiation belts at geosynchronous orbit: Statistics and behavior during high‐speed stream‐driven storms

Borovsky, Joseph E.; Cayton, T. E.; Denton, M. H.; Belian, R. D.; Christensen, R. A.; Ingraham, J. C.

doi:10.1002/2016ja022520

Cited by 24 publications

(17 citation statements)

References 142 publications

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“…At geosynchronous orbit, substorm‐injected electrons have typical kinetic energies of 50 to 300 keV (Birn et al, , ; Cayton et al, ; Denton et al, ; Lezniak et al, ), although under special circumstances electrons with energies of 1 MeV can be injected by substorms (cf. Borovsky et al, ; Ingraham et al, ).…”

Section: Simulation Resultsmentioning

confidence: 99%

“…Compressional magnetic pumping should also act on the proton radiation belt with pitch angle scattering occurring via proton interactions with EMIC waves (Shoji & Omura, ; Søraas et al, ) or with whistler‐mode hiss (Kozyra et al, ; Villalon & Burke, ). Examining the proton radiation belt at geosynchronous orbit during 94 high‐speed stream‐driven storms, Borovsky et al () found that the flux of 1 MeV protons systematically increases in the day prior to the onset of a high‐speed stream‐driven storm. At such times before the storm onset, (1) the solar wind passing the Earth is often sector reversal region plasma that is very inhomogeneous (Borrini et al, ; Gosling et al, ) with strong temporal variations in the solar wind ram pressure, and (2) the plasmapause often extends to beyond geosynchronous orbit owing the refilling of the outer plasmasphere (Borovsky & Steinberg, ; Denton & Borovsky, ).…”

Section: Discussionmentioning

confidence: 99%

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The Contribution of Compressional Magnetic Pumping to the Energization of the Earth's Outer Electron Radiation Belt During High‐Speed Stream‐Driven Storms

2017

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Compressional magnetic pumping is an interaction between cyclic magnetic compressions and pitch angle scattering with the scattering acting as a catalyst to allow the cyclic compressions to energize particles. Compressional magnetic pumping of the outer electron radiation belt at geosynchronous orbit in the dayside magnetosphere is analyzed by means of computer simulations, wherein solar wind compressions of the dayside magnetosphere energize electrons with electron pitch angle scattering by chorus waves and by electromagnetic ion cyclotron (EMIC) waves. The magnetic pumping is found to produce a weak bulk heating of the electron radiation belt, and it also produces an energetic tail on the electron energy distribution. The amount of energization depends on the robustness of the solar wind compressions and on the amplitude of the chorus and/or EMIC waves. Chorus‐catalyzed pumping is better at energizing medium‐energy (50–200 keV) electrons than it is at energizing higher‐energy electrons; at high energies (500 keV–2 MeV) EMIC‐catalyzed pumping is a stronger energizer. The magnetic pumping simulation results are compared with energy diffusion calculations for chorus waves in the dayside magnetosphere; in general, compressional magnetic pumping is found to be weaker at accelerating electrons than is chorus‐driven energy diffusion. In circumstances when solar wind compressions are robust and when EMIC waves are present in the dayside magnetosphere without the presence of chorus, EMIC‐catalyzed magnetic pumping could be the dominant energization mechanism in the dayside magnetosphere, but at such times loss cone losses will be strong.

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Section: Simulation Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

The Contribution of Compressional Magnetic Pumping to the Energization of the Earth's Outer Electron Radiation Belt During High‐Speed Stream‐Driven Storms

2017

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“…In addition to magnetic field amplitude and orientation, the solar wind, a supersonic plasma, is characterized by its dynamic pressure, Mach number, and ion and electron temperatures. These parameters can be combined to calculate different complex coupling functions describing the efficiency of solar wind‐driven magnetosphere dynamics (e.g., Balikhin et al, ; Borovsky et al, , and references therein) or can be used alone to investigate the impact of the solar wind on the magnetosphere (e.g., Sergeev et al, ; Yue et al, , and references therein).…”

Section: Introductionmentioning

confidence: 99%

Near‐Earth Solar Wind: Plasma Characteristics From ARTEMIS Measurements

2018

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The interaction between the solar wind and Earth's magnetosphere is the main driver of magnetosphere dynamics because many important processes in Earth's inner and outer magnetosphere can be considered as responses to solar wind parameter variations. Therefore, accurate measurements of these parameters (density, velocity, ion, and electron temperature) in the near‐Earth solar wind is critical for understanding and forecasting magnetosphere dynamics. Moreover, the solar wind is a natural laboratory for investigation of plasma turbulence, including the configuration and dynamics of coherent plasma structures (such as large‐amplitude waves, discontinuities, and interplanetary shocks). A major solar wind parameter database, the OMNI database, consists of solar wind proton characteristics and magnetic field parameters but does not provide electron characteristics. We consider a supplementary solar wind data set compiled by observations of the two Acceleration, Reconnection, Turbulence and Electrodynamics of the Moon's Interaction with the Sun (ARTEMIS) probes. We compare characteristics available in both the ARTEMIS and OMNI data sets. We also describe characteristics of solar wind electron components measured by ARTEMIS (density, temperature, and anisotropy). Finally, we discuss opportunities for investigation of the near‐Earth solar wind provided by the ARTEMIS data set.

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“…Для потоков электронов с Е >1 МэВ наблюдались максимальные значения J m ≥ 10 7 см -2 с -1 [Савенко и др., 1979]. По данным работы [Borovsky et al, 2016]…”

Section: Discussionunclassified

Sky-distribution of intensity of synchrotron radio emission of relativistic electrons trapped in Earth’s magnetic field

Клименко¹

2017

Solnechno-Zemnaya Fizika

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Аннотация. Представлены расчеты интенсивности синхротронного радиоизлучения радиационного пояса (РП) с пространственным гауссовским распределением плотности электронов по L-оболочкам дипольного магнитного поля и релятивистским максвелловским распределением по энергии. Результаты вычислений находятся в хорошем согласии с измерениями интенсивности синхротронного излучения электронов искусственного РП во время ядерного эксперимента "Starfish". Получены двумерные распределения радиояркости в координатах азимутзенитный угол для наблюдателя, находящегося на поверхности Земли. Максимумы интенсивности излучения, расположенные к западу и к востоку от меридиана, в несколько раз превышают максимальный уровень излучения в плоскости меридиана. Построены двумерные распределения интенсивности излучения в децибелах относительно уровня фонового галактического радиошума. Чтобы интенсивность синхротронного излучения в плоскости меридиана превысила уровень космического фона на 0.1 дБ (порог чувствительности риометра), необходимы изотропные потоки релятивистских электронов (Е ~ 1 МэВ) более 10 7 см -2 с -1 .Ключевые слова: синхротронное радиоизлучение, релятивистские электроны, радиационный пояс, дипольное магнитное поле.Abstract. This paper presents the calculations of synchrotron radio emission intensity from Van Allen belts with Gaussian space distribution of electron density across L-shells of a dipole magnetic field, and with Maxwell's relativistic electron energy distribution. The results of these calculations come to a good agreement with measurements of the synchrotron emission intensity of the artificial radiation belt's electrons during the Starfish nuclear test. We have obtained two-dimensional distributions of radio brightness in azimuth -zenith angle coordinates for an observer on Earth's surface. The westside and eastside intensity maxima exceed several times the maximum level of emission in the meridian plane. We have also constructed two-dimensional distributions of the radio emission intensity in decibels related to the background galactic radio noise level. Isotropic fluxes of relativistic electrons (Е ~ 1 MeV) should be more than 10 7 cm -2 s -1 for the synchrotron emission intensity in the meridian plane to exceed the cosmic noise level by 0.1 dB (riometer sensitivity threshold).

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The proton and electron radiation belts at geosynchronous orbit: Statistics and behavior during high‐speed stream‐driven storms

Cited by 24 publications

References 142 publications

The Contribution of Compressional Magnetic Pumping to the Energization of the Earth's Outer Electron Radiation Belt During High‐Speed Stream‐Driven Storms

The Contribution of Compressional Magnetic Pumping to the Energization of the Earth's Outer Electron Radiation Belt During High‐Speed Stream‐Driven Storms

Near‐Earth Solar Wind: Plasma Characteristics From ARTEMIS Measurements

Sky-distribution of intensity of synchrotron radio emission of relativistic electrons trapped in Earth’s magnetic field

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