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Numerical Simulations of Solar Disturbances and their Interplanetary Consequences

Published online by Cambridge University Press:  19 July 2016

M. Dryer ,
S. T. Wu  and
T. R. Detman
M. Dryer
Affiliation:
1Space Environment Laboratory National Oceanic and Atmospheric Administration R/E/SE, 325 Broadway Boulder, Colorado 80303-3328 USA
S. T. Wu
Affiliation:
2Center for Space Plasma and Aeronomic Research, and Department of Mechanical Engineering University of Alabama in Huntsville Huntsville, Alabama 35899 USA
T. R. Detman
Affiliation:
1Space Environment Laboratory National Oceanic and Atmospheric Administration R/E/SE, 325 Broadway Boulder, Colorado 80303-3328 USA

Abstract

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Responses of the solar atmosphere and interplanetary medium to simulated solar disturbances were studied by time-dependent, MHD numerical simulations. This deterministic initial-boundary value problem was attacked in the classical way: a representative steady state is first established, then input parameters at the lower near-Sun boundary are perturbed. We discuss a number of 2- and 3-dimensional examples of coronal mass ejection (CME) simulations and some current controversies concerning the basic process of CME initiation. Footpoint shearing motion is tested to see whether it can provide a reasonable mechanism for CME development from arch filament configurations.

We also demonstrate possible interplanetary consequences to CME-like disturbances by using 3-D simulations to determine the dynamic response of the solar wind to a plasmoid injection from an eruptive filament or prominence. We also discuss the separate possibility whereby a plasmoid may be generated in the interplanetary medium by a solar-generated shock that propagates through a heliospheric current sheet. Application of the 3-D model for the interpretation of interplanetary scintillation observations is also discussed.

Type
VII. Magnetic Reconnection and Coronal Evolution
Information
Symposium - International Astronomical Union , Volume 142: Basic Plasma Processes on the Sun , 1990 , pp. 331 - 340
Copyright
Copyright © Kluwer 1990 

References

REFERENCES

Burlaga, L. F. (1989), in Marsch, E. and Schwenn, R. (eds.), Physics of the Inner Heliosphere, D. Reidel Publ. Co., Dordrecht, in press.Google Scholar
Detman, T. R., Dryer, M., Yeh, T., Han, S. M., Wu, S. T., and McComas, D. J. (1990), in preparation.Google Scholar
Dryer, M. (1982), Space Sci. Rev., 33, 233.Google Scholar
Dryer, M., Detman, T. R., Wu, S. T., and Han, S. M. (1989), Adv. Space Res., 9(4), 75.Google Scholar
Dryer, M., Smith, Z. K., and Wu, S. T. (1988), Astrophys. Space Sci., 144, 407425.Google Scholar
Dryer, M., and Wu, S. T. (1985), J. Geophys. Res., 90, 559.Google Scholar
Dryer, M., Wu, S. T., and Gislason, G. (1983), in Neugebauer, M. (ed.), Proceedings of the Fifth International Solar Wind Conference, NASA Conference Publ. No. 2280, p. 735.Google Scholar
Gold, T. (1959), J. Geophys. Res., 64, 1665.Google Scholar
Gosling, J. T. (1989), in Russell, C. T. (ed.), Physics of Magnetic Flux Ropes, Amer. Geophys. Union Monograph, in press.Google Scholar
Han, S. M., Wu, S. T., and Dryer, M. (1988), Computers & Fluids, 16, 82.Google Scholar
Hewish, A. (1988), Solar Phys., 116, 195.CrossRefGoogle Scholar
Hewish, A., and Bravo, S. (1986), Solar Phys., 106, 185.Google Scholar
Hewish, A., and Duffett-Smith, P. J. (1987), Planet. Space Sci., 35, 487.Google Scholar
Howard, R. A., Sheeley, N. R. Jr., Michels, D. J., and Koomen, M. J. (1985), J. Geophys. Res., 90, 8173.Google Scholar
Klimchuk, J.A. (1989), in Phillips, K. (ed.), Proceedings of the Thermal-Nonthermal Flares Workshop II, Rutherford-Appleton Laboratory Report, RAL-89-102, Didcot, U.K., pp. 16 to 1-8.Google Scholar
Munro, R. H., and Sime, D. G. (1985), Solar Phys., 97, 191.Google Scholar
Tappin, S. M., Dryer, M., Han, S. M., and Wu, S. T. (1988), Planet. Space Sci., 36, 1155.Google Scholar
Webb, D. F., and Hundhausen, A. J. (1987), Solar Phys., 108, 383401.Google Scholar
Wu, S. T., Song, M. T., Martens, P., and Dryer, M. (1990), in preparation.Google Scholar
Wu, S. T., Wang, S., Wang, A. H., and Dryer, M. (1988), Adv. Space Res., 8(11), 221226.Google Scholar