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A Review of Stellar Flares and Their Characteristics

Published online by Cambridge University Press:  12 April 2016

B. R. Pettersen
B. R. Pettersen*
Affiliation:
Institute of Theoretical Astrophysics, University of Oslo, P.O. Box 1029 Blindern, N-0315 Oslo 3, Norway

Abstract

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We review the flaring activity of stars across the HR-diagram. Brightenings have been reported along the entire Main Sequence and in many stars off the Main Sequence. Some stars are decidedly young, others are in advanced stages of stellar evolution. Flares are common on stars with outer convection zones and outbursts have been reported also on other types of stars, although confirmations are needed for some of them.

Analyses of flare occurrence sometimes find flares to be randomly distributed in time, and sometimes indicate a tendency for flares to come in groups. Preferred active longitudes have been suggested. Recent solar results, where the occurrence rate for flares is found to exhibit a periodicity of 152 days, suggest that stellar flare data should be reanalyzed over long time baselines to see if the present confusing situation can be resolved.

The radiation from stellar flares is dominated by continuum emission and about equal amounts of energy have been recorded in the optical, UV, and X-ray regions of the spectrum. In solar flares strong continuum emission is rarely recorded and a large collection of bright emission lines takes prominence. Small flares occur more frequently than large ones and the latter have longer time-scales. Flare energies can exceed 1037 erg. The most productive flare stars are those where the convective envelopes occupy large volumes. Slow stellar rotation rates are believed to reduce the level when the star has been braked significantly from its young rotation rate.

Type
Research Article
Information
International Astronomical Union Colloquium , Volume 104 , Issue 1: Solar and Stellar Flares , 1989 , pp. 299 - 312
Copyright
Copyright © Kluwer 1989

References

Bai, T. and Sturrock, P. A.: 1987, Nature 327, 601.Google Scholar
Copeland, H., Jensen, J. O., and Jørgensen, H. E.: 1970, Astron. Astrophys. 5, 12.Google Scholar
Doyle, J. G.: 1987, Astron. Astrophys. 177, 201.Google Scholar
Gershberg, R. E. and Shakhovskaya, N. I.: 1973, Nature Phys. Sci. 242, 85.Google Scholar
Haro, G. and Chavira, E.: 1955, Bol. Obs. Tonantzintla Tacubaya, No. 12.Google Scholar
Kunkel, W. E.: 1969, in Kumar, S. S. (ed.), Low Luminosity Stars, p. 195.Google Scholar
Kunkel, W. E.: 1974, Nature Phys. Sä. 248, 571.Google Scholar
Kunkel, W. E.: 1975, in Sherwood, V. E. and Plaut, L. (eds.), ‘Variable Stars and Stellar Evolution', IAU Symp. 67, 15.Google Scholar
Lacy, C. H., Moffett, T. J., and Evans, D. S.: 1976, Astrophys. J. Suppl. 30, 85.CrossRefGoogle Scholar
Melikian, N. D. and Grandpierre, A.: 1984, Inf. Bull. Var. Stars, No. 2683.Google Scholar
Novotný, E.: 1973, Introduction to Stellar Atmospheres and Interiors, Oxford University Press, Oxford, p. 373ff.Google Scholar
Oskanyan, V. S. and Terebizh, V. Yu.: 1971, Astrofizika 7, 83.Google Scholar
Pazzani, V. and Rodonò, M.: 1981, Astrophys. Space Sci. 77, 347.Google Scholar
Pettersen, R. R.: 1980, Astron. Astrophys. 82, 53.Google Scholar
Pettersen, B. R.: 1988, in Havnes, O. et al. (eds.), Activity in Cool Star Envelopes, Kluwer Academic Publishers, Dordrecht, Holland, p. 49.Google Scholar
Pettersen, B. R., Coleman, L. A., and Evans, D. S.: 1984, Astrophys. J. Suppl. 54, 375.Google Scholar
Pettersen, B. R., Panov, K. P., Sandmann, W. H., and Ivanova, M. S.: 1986, Astron. Astrophys. Suppl. 66, 235.Google Scholar
Rosner, R.: 1980, in Dupree, A. K. (ed.), Cool Stars, Stellar Systems and the Sun, SAO Special Report No. 389, p. 79.Google Scholar