Issue
J. Space Weather Space Clim.
Volume 3, 2013
EU-FP7 funded space weather projects
Article Number A10
Number of page(s) 6
DOI https://doi.org/10.1051/swsc/2013034
Published online 06 March 2013
  • Agueda, N., D. Lario, R. Vainio, B. Sanahuja, E. Kilpua and S. Pohjolainen, et al., Modeling solar near-relativistic electron events. Insights into solar injection and interplanetary transport conditions, A&A, 507, 981, 2009. [NASA ADS] [CrossRef] [EDP Sciences]
  • Agueda, N., R. Vainio, D. Lario, and B. Sanahuja, Injection and interplanetary transport of near-relativistic electrons: modeling the impulsive event on 2000 May 1, Astrophys. J., 675, 1601, 2008. [NASA ADS] [CrossRef]
  • Agueda, N., R. Vainio, D. Lario, and B. Sanahuja, Solar near-relativistic electron observations as a proof of a back-scatter region beyond 1 AU during the 2000 February 18 event, A&A, 519, A36, 2010. [NASA ADS] [CrossRef] [EDP Sciences]
  • Beeck, J., and G. Wibberenz, Pitch angle distributions of solar energetic particles and the local scattering properties of the interplanetary medium, Astrophys. J., 311, 437, 1986. [NASA ADS] [CrossRef]
  • Bobik, P., G. Boella, M.J. Boschini et al., Systematic investigation of solar modulation of galactic protons for solar cycle 23 using a Monte Carlo approach with particle drift effects and latitudinal dependence, Astrophys. J., 745, 132, 2012. [NASA ADS] [CrossRef]
  • Dröge, W., Particle scattering by magnetic fields, Space Sci. Rev., 93, 121, 2000. [NASA ADS] [CrossRef]
  • Dröge, W., Solar particle transport in a dynamical quasi-linear theory, Astrophys. J., 589, 1027, 2003. [NASA ADS] [CrossRef]
  • Dröge, W., and Y.Y. Kartavykh, Testing transport theories with solar energetic particles, International Cosmic Ray Conference, 1, 159–162, 2008.
  • Dröge, W., and Y.Y. Kartavykh, Testing transport theories with solar energetic particles, Astrophys. J., 693, 69, 2009. [NASA ADS] [CrossRef]
  • Dröge, W., Y.Y. Kartavykh, B. Klecker, and G.A. Kovaltsov, Anisotropic three-dimensional focused transport of solar energetic particles in the inner heliosphere, Astrophys. J., 709, 912, 2010. [NASA ADS] [CrossRef]
  • Earl, J.A., and J.R. Jokipii, Numerical descriptions of cosmic-ray transport, Proc. 19th Int. Cosmic Ray Conf. (La Jolla), 4, 396, 1985.
  • Gervasi, M., P.G. Rancoita, I.G. Usoskin, and G.A. Kovaltsov, Monte-Carlo approach to galactic cosmic ray propagation in the heliosphere, Nucl. Phys. B Proc. Suppl., 78, 26, 1999. [CrossRef]
  • Hasselmann, K., and G. Wibberenz, A note on the parallel diffusion coefficient, Astrophys. J., 162, 1049, 1970. [NASA ADS] [CrossRef]
  • Jaekel, U., and R. Schlickeiser, Quasilinear theory of cosmic ray pitch-angle diffusion for generalized turbulence models, Ann. Geophys., 10, 541, 1992.
  • Jokipii, J.R., Cosmic-ray propagation. I. Charged particles in a random magnetic field, Astrophys. J., 146, 480, 1966. [NASA ADS] [CrossRef]
  • Jokipii, J.R., and D.A. Kopriva, Effects of particle drift on the transport of cosmic rays. III – Numerical models of galactic cosmic-ray modulation, Astrophys. J., 234, 384, 1979. [NASA ADS] [CrossRef]
  • Jokipii, J.R., and E.H. Levy, Effects of particle drifts on the solar modulation of galactic cosmic rays, Astrophys. J., 213, L85, 1977. [NASA ADS] [CrossRef]
  • Kallenrode, M.-B., G. Wibberenz, and S. Hucke, Propagation conditions of relativistic electrons in the inner heliosphere, Astrophys. J., 394, 351, 1992. [NASA ADS] [CrossRef]
  • Kocharov, L., R. Vainio, G.A. Kovaltsov, and J. Torsti, adiabatic deceleration of solar energetic particles as deduced from Monte Carlo simulations of interplanetary transport, Sol. Phys., 182, 195, 1998. [NASA ADS] [CrossRef]
  • Kunow, H., G. Wibberenz, G. Green, R. Müller-Mellin, and M.-B. Kallenrode, Energetic particles in the inner solar system, in: Physics of the Inner Heliosphere II. Particles, Waves and Turbulence, ed. Schwenn, E., Marsch, E., New York: Springer, 243–342, 1991. [CrossRef]
  • Lario, D., B. Sanahuja, and A.M. Heras, Energetic particle events: efficiency of interplanetary shocks as 50 keV < 100 MeV proton accelerators, Astrophys0. J., 509, 415, 1998. [NASA ADS] [CrossRef]
  • Palmer, I.D., and J.R. Jokipii, Monte-Carlo model of pitch-angle scattering in solar cosmic ray events, International Cosmic Ray Conference, 3, 381–384, 1981.
  • Parker, E.N., The passage of energetic charged particles through interplanetary space, Planet Space Sci., 13, 9, 1965. [NASA ADS] [CrossRef]
  • Pei, C., J.R. Jokipii, and J. Giacalone, Effect of a random magnetic field on the onset times of solar particle events, Astrophys. J., 641, 1222, 2006. [CrossRef]
  • Roelof, E.C., Propagation of solar cosmic rays in the interplanetary magnetic field, Lectures in High-Energy Astrophysics (NASA SP-199), eds. H., Ögelman and J.R. Wayland, Washington, DC: NASA, 111, 1969.
  • Ruffolo, D., Effect of adiabatic deceleration on the focused transport of solar cosmic rays, Astrophys. J., 442, 861, 1995. [NASA ADS] [CrossRef]
  • Sandroos, A., and R. Vainio, Diffusive shock acceleration to relativistic energies in the solar corona, A&A, 507, L21, 2009. [NASA ADS] [CrossRef] [EDP Sciences]
  • Schlickeiser, R., Cosmic ray astrophysics, Astronomy and Astrophysics Library; Physics and Astronomy Online Library, Springer: Berlin, ISBN 3-540-66465-3, 2002. [CrossRef]
  • Torsti, J., L.G. Kocharov, R. Vainio, A. Anttila, and G.A. Kovaltsov, The 1990 May 24 solar cosmic-ray event, Sol. Phys., 166, 135, 1996. [NASA ADS] [CrossRef]
  • Vainio, R., Monte-Carlo simulations of interplanetary transport and acceleration of energetic particles. PhD thesis, Department of Physics, FIN-20014 Turku University, Finland, 1998.
  • Vainio, R., Charged-particle resonance conditions and transport coefficients in slab-mode waves, Astrophys. J., 131, 519, 2000. [NASA ADS] [CrossRef]
  • Vainio, R., L. Desorgher, D. Heynderickx, et al., Dynamics of the Earth's particle radiation environment, Space Sci. Rev., 147, 187, 2009. [NASA ADS] [CrossRef]
  • Wang, Y., G. Qin, and M. Zhang, Effects of perpendicular diffusion on energetic particles accelerated by the interplanetary Coronal Mass Ejection shock, Astrophys. J., 752, 37, 2012. [CrossRef]
  • Watermann, J., R. Vainio, J. Lilensten, A. Belehaki, and M. Messerotti, The state of space weather scientific modeling: an introduction, Space Sci. Rev., 147, 111, 2009. [CrossRef]

Current usage metrics show cumulative count of Article Views (full-text article views including HTML views, PDF and ePub downloads, according to the available data) and Abstracts Views on Vision4Press platform.

Data correspond to usage on the plateform after 2015. The current usage metrics is available 48-96 hours after online publication and is updated daily on week days.

Initial download of the metrics may take a while.