Abstract
Hyder advocated the idea that the optical (Hα) flares can be identified with the response of the solar chromosphere to an infalling material stream resulting from the ‘disparition brusque’ of a prominence. Since some flares are observed without any apparent association with infalling streams, in this paper we examine the possibility of identifying the optical flare with the response of the chromosphere to a supersonic disturbance, i.e., a shock, propagating downward. The undisturbed chromosphere is represented by the Harvard-Smithsonian Reference Atmosphere and the evolution of the shock is evaluated with the use of the CCW (Chisnell, Chester, Whitham) approximation based on the theory of characteristics. It is shown that the chromosphere is heated by the shock and that radiation is enhanced, and that the enhanced radiation terminates the shock around the height of the temperature minimum. Numerical results obtained and possible future improvements of this type of study are discussed.
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The National Center for Atmospheric Research is sponsored by the National Science Foundation.
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Nakagawa, Y., Wu, S.T. & Han, S.M. A kinematic model of a solar flare. Sol Phys 30, 111–120 (1973). https://doi.org/10.1007/BF00156179
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DOI: https://doi.org/10.1007/BF00156179