INTERPLANETARY PROPAGATION OF SOLAR ENERGETIC PARTICLE HEAVY IONS OBSERVED AT 1 AU AND THE ROLE OF ENERGY SCALING

INTERPLANETARY PROPAGATION OF SOLAR ENERGETIC PARTICLE HEAVY IONS OBSERVED AT 1 AU AND THE ROLE OF ENERGY SCALING

We have studied ~0.3 to >100 MeV nucleon super(-1) H, He, O, and Fe in 17 large western hemisphere solar energetic particle events (SEP) to examine whether the often observed decrease of Fe/O during the rise phase is due to mixing of separate SEP particle populations, or is an interplanetary tran...

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Veröffentlicht in:The Astrophysical journal 2012-12, Vol.761 (2), p.1-27
Hauptverfasser: MASON, G. M, LI, G, COHEN, C. M. S, DESAI, M. I, HAGGERTY, D. K, LESKE, R. A, MEWALDT, R. A, ZANK, G. P
Format: Artikel
Sprache:eng
Schlagworte:
ACCELERATION
ASTRONOMY
ASTROPHYSICS
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
Computer simulation
COMPUTERIZED SIMULATION
CONVECTION
Convection modes
Deceleration
DIFFUSION
Earth, ocean, space
ELEMENT ABUNDANCE
Energetic particles
Exact sciences and technology
Fittings
HELIUM IONS
INCLINATION
IRON IONS
KEV RANGE
KINETIC ENERGY
MEAN FREE PATH
MEV RANGE
MONTE CARLO METHOD
OXYGEN IONS
Pitch angle
SOLAR PARTICLES
Spectra
SUN
Transport
TRANSPORT THEORY
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Zusammenfassung:We have studied ~0.3 to >100 MeV nucleon super(-1) H, He, O, and Fe in 17 large western hemisphere solar energetic particle events (SEP) to examine whether the often observed decrease of Fe/O during the rise phase is due to mixing of separate SEP particle populations, or is an interplanetary transport effect. Using an interplanetary transport model that includes effects of focusing, convection, adiabatic deceleration, and pitch angle scattering we have fit the particle spectral forms and intensity profiles over a broad range of conditions where the 1 AU intensities were reasonably well connected to the source and not obviously dominated by local shock effects. Our model follows individual particles with a Monte Carlo calculation, making it possible to determine many properties and effects of the transport. We find that the energy scaling feature is preserved, and that the model is reasonably successful at fitting the magnitude and duration of the Fe/O ratio decrease.
ISSN:0004-637X
1538-4357
DOI:10.1088/0004-637X/761/2/104