Abstract
At the Sun-Earth distance of one astronomical unit (1 AU), the solar wind is known to be strongly supersonic and super Alfvenic with Mach and Alfven numbers being on average 12 and 9 respectively. Also, solar wind densities (average ∼10cm-3) and velocities (average ∼450kms-1) at 1AU, are known to be inversely correlated with low velocities having higher than average densities andvice versa. However, on May 11 and 12 1999 the Earth was engulfed by an unusually low density (< 0.1cm-3) and low velocity (< 350km s-1) solar wind with an Alfven Mach number significantly less than 1. This was a unique low-velocity, low-density, sub-Alfvénic solar wind flow which spacecraft observations have shown lasted more than 24 hours. One consequence of this extremely tenuous solar wind was a spectacular expansion of the Earth’s magnetosphere and bow shock. The expanding bow shock was observed by several spacecraft and reached record upstream distances of nearly 60 Earth radii, the lunar orbit. The event was so dramatic that it has come to be known asthe solar wind disappearance event. Though extensive studies of this event were made by many authors in the past, it has only been recently shown that the unusual solar wind flows characterizing this event originated from a small coronal hole in the vicinity of a large active region on the Sun. These recent results have put to rest speculation that such events are associated with global phenomenon like the periodic solar polar field reversal that occurs at the maximum of each solar cycle. In this paper we revisit the 11 May 1999 event, look at other disappearance events that have ocurred in the past, examine the reasons why speculations about the association of such events with global phenomena like solar polar field reversals were made and also examine the role of transient coronal holes as a possible solar source for such events.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Balasubramanian, V., Janardhan, P., Srinivasan, S., Ananthakrishnan, S. 2003, IPS observations of the solar wind disappearance event of May 1999;J. Geophys. Res.,108, 1121–1131.
Crooker, N. U., Shodhan, S., Gosling, J. T., Simmerer, J., Lepping, R. P., Steinberg, J. T., Kahler, S. W. 2000, Density extremes in the solar wind;Geophys. Res. Lett.,27, 3769–3772.
Farrugia, C. J., Singer, H. J., Evans, D., Berdichevsky, D., Scudder, J. D., Ogilvie, K. W., Fitzenreiter, R. J., Russell, C. T. 2000, Response of the equatorial and polar magnetosphere to the very tenuous solar wind on May 11, 1999;Geophys. Res. Lett.,27, 3773–3776.
Gosling, J.T., Asbridge, J. R., Bame, S. J., Feldman, W. C., Zwickl, R. G., Pashmann, G., Sckopke, N., Russell, C. T. 1982, A sub-Alfvenic solar wind: interplanetary and magnetosheath observations;J. Geophys. Res.,87, 239–245.
Hakamada, K., Kojima, M. 1999, Solar wind speed and expansion rate of the coronal magnetic field during carrington rotation 1909;Solar. Phys.,187, 115–122.
Janardhan, P., Fujiki, K., Kojima, M., Tokumaru, M., Hakamada, K. 2006, Resolving the enigmatic solar wind disappearance event of May 1999;J. Geophys. Res.,110, A08101.
Kahler, S. W., Hudson, H. S. 2001, Origin and development of transient coronal holes;J. Geophys. Res.,106, 29,239–29,248.
Kojima, M., Fujiki, K., Ohmi, M., Tokumaru, M., Yokobe, A., Hakamada, K. 1999, Low speed solar wind from the vicinity of solar active regions;J. Geophys. Res.,104, 16,993–17,003.
Neugebauer, M., Forsyth, R. J., Galvin, A. B., Harvey, K. L., Hoeksema, J. T., Lazarus, A. J., Lepping, R. P., Linker, J. A., Mikic, Z., Steinberg, J. T., von Steiger, R., Wang, Y.-M., Wimmer-Schweingruber, R. F 1998, Spatial structure of the solar wind and comparisons with solar data and models;J. Geophys. Res.,103, 14,587–14,600.
Nolte, J. T., Krieger, A. S., Timothy, A. F., Gold, R. E., Roelof, E. C., Vaiana, G., Lazarus, A. J., Sullivan, J. D., McIntosh, P. S. 1976, Coronal holes as sources of solar wind;Sol. Phys.,46, 303–322.
Richardson, I. G., Berdichevsky, D., Desch, M. D., Farrugia, G. J. 2000, Solar-cycle variation of low density solar wind during more than 3 solar cycles;Geophys. Res. Lett.,27, 3761–3764.
Rust, D. M. 1983, Coronal Disturbances and their Terrestrial Effects;Space Sci. Rev.,34, 21–24.
Schwenn, R. 1983, The average solar wind in the inner heliosphere: structure and slow variations;Solar Wind 5 [NASA Conf. Pub. 2280], (ed.) M. Neugebauer, pp. 489–508.
Sheeley, N. R. Jr., Swanson, E. T., Wang, Y.-M. 1991, Out of the ecliptic tests of the inverse correlation between solar wind speed and coronal expansion factor;J. Geophys. Res.,96, 13,861–13,868.
Usmanov, A. V., Goldstien, M. L., Farrell, W. M. 2000, A view of the inner heliosphere during the May 10–11, 1999 low density anomaly;Geophys. Res. Lett.,27, 3765–3768.
Usmanov, A. V., Farrell, W M., Ogilvie, K. W., Goldstien, M. L. 2003, The sub-Alfvenic solar wind and low density anomalies;Proc. EGS-AGU-EUG Joint Asembly.
Vats, H. O., Sawant, H. S., Oza, R., Iyer, K. N., Jadhav, R. 2001, Interplanetary scintillation observations of the solar wind disappearance event of May 1999;J. Geophys. Res.,106,25, 121–25, 124.
Wang, Y.-M., Sheeley Jr. 1990, Solar wind speed and coronal flux-tube expansion;Astrophys. J.,355, 726–732.
Wang, Y.-M., Sheeley, N. R. Jr., Walters, J. H., Brukner, G. E., Howard, R. A., Michels, D. J., Lamy, P. L., Schwenn, R., Simnett, G. M. 1998, Origin of streamer material in the outer corona;Astrophys. J.,498, L165-L168.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Janardhan, P. Enigmatic solar wind disappearance events – Do we understand them?. J Astrophys Astron 27, 201–207 (2006). https://doi.org/10.1007/BF02702522
Issue Date:
DOI: https://doi.org/10.1007/BF02702522