Abstract
The magnetic field in the heliosphere evolves in response to the photospheric field at its base. This evolution, together with the rotation of the Sun, drives space weather through the continually changing conditions of the solar wind and the magnetic field embedded within it. We combine observations and simulations to investigate the sources of the heliospheric field from 1996 to 2001. Our algorithms assimilate SOHO/MDI magnetograms into a flux-dispersal model, showing the evolving field on the full sphere with an unprecedented duration of 5.5 yr and temporal resolution of 6 hr. We demonstrate that acoustic far-side imaging can be successfully used to estimate the location and magnitude of large active regions well before they become visible on the solar disk. The results from our assimilation model, complemented with a potential-field source-surface model for the coronal and inner-heliospheric magnetic fields, match Yohkoh/SXT and KPNO/He 10830 Å coronal hole boundaries quite well. Even subject to the simplification of a uniform, steady solar wind from the source surface outward, our model matches the polarity of the interplanetary magnetic field (IMF) at Earth ∼3% of the time during the period 1997–2001 (independent of whether far-side acoustic data are incorporated into the simulation). We find that around cycle maximum, the IMF originates typically in a dozen disjoint regions. Whereas active regions are often ignored as a source for the IMF, the fraction of the IMF that connects to magnetic plage with absolute flux densities exceeding 50 Mx cm−2 increases from ≲10% at cycle minimum up to 30–50% at cycle maximum, with even direct connections between sunspots and the heliosphere. For the overall heliospheric field, these fractions are ≲1% to 20–30%, respectively. Two case studies based on high-resolution TRACE observations support the direct connection of the IMF to magnetic plage, and even to sunspots. Parallel to the data assimilation, we run a pure simulation in which active regions are injected based on random selection from parent distribution functions derived from solar data. The global properties inferred for the photospheric and heliospheric fields for these two models are in remarkable agreement, confirming earlier studies that no subtle flux-emergence patterns or field-dispersal properties are required of the solar dynamo beyond those that are included in the model in order to understand the large-scale solar and heliospheric fields.
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References
Altschuler, M., Trotter, D., and Orrall, F.: 1972, Solar Phys. 26, 354.
Axford, W. I. and McKenzie, J. F.: 1991, Solar Wind Seven, Proceedings of the 3rd COSPAR Colloquium, p. 1.
Balogh, A. and Smith, E. J.: 2001, Space Sci. Rev. 97, 147.
Berger, T. E. and Lites, B. W.: 2002, Solar Phys., in preparation.
Brajša, R., Wöhl, H., Vršnak, B., Ruždjak, D., Sudar, D., Roša, D., and Hržina, D.: 2002, Solar Phys. 206, 241.
Braun, D. C. and Lindsey, C.: 2001, Astrophys. J. 560, L189.
Brouwer, M. P. and Zwaan, C.: 1990, Solar Phys. 129, 221.
DeVore, C. R., Sheeley, N. R., and Boris, J. P.: 1984, Solar Phys. 92, 1.
DeVore, C. R., Sheeley, N. R., Boris, J. P., Young, T. R., and Harvey, K. L.: 1985, Aust. J. Phys. 38, 999.
Golub, L. and Pasachoff, J.: 1997, The Solar Corona, Cambridge University Press, Cambridge.
Gosling, J. T.: 1996, Ann. Rev. Astron. Astrophys. 34, 35.
Hagenaar, H. J., Schrijver, C. J., Title, A. M., and Shine, R. A.: 1999, Astrophys. J. 511, 932.
Handy, B. N., Acton, L. W., Kankelborg, C. C. et al.: 1999, Solar Phys. 187, 229.
Harvey, K. L.: 1993, Ph.D. Thesis, Astronomical Institute, Utrecht University.
Harvey, K. L. and Zwaan, C.: 1993, Solar Phys. 148, 85.
Hoeksema, J. T.: 1984, Ph.D. Thesis, Stanford University, Stanford, Ca.
Huber, M., Foukal, P., Noyes, R., Reeves, E., Schmahl, E., Timothy, J., Vernazza, J., and Withbroe, G.: 1974, Astrophys J. 194, L115.
Hundhausen, A. J.: 1972, Coronal Expansion and Solar Wind,Springer-Verlag, Berlin.
Kahler, S.W. and Hudson, H. S.: 2001, J. Geophys. Res. 106, 29239.
Komm, R. W., Howard, R. F., and Harvey, J. W.: 1993, Solar Phys. 147, 207.
Leighton, R. B.: 1964, Astrophys. J. 140, 1547.
Levine, R. H.: 1982, Solar Phys. 79, 203.
Levine, R. H., Altschuler, M. D., Harvey, J. W., and Jackson, B. V.: 1977, Astrophys. J. 215, 636.
Lindsey, C. and Braun, D. C.: 2000, Solar Phys. 192, 261.
Lockwood, M.: 2002, Astron. Astrophys. 382, 678.
Luhmann, J. G., Li, Y., Arge, N., Gazis, P. R., and Ulrich, R.: 2002, J. Geophys. Res. 107, 10.1029.
Mosher, J. M.: 1977, The Magnetic History of Solar Active Regions, CalTech, Pasadena, Ca.
Ness, N. F. and Wilcox, J. M.: 1964, Phys. Rev. Lett. 13, 461.
Neugebauer, M., Forsyth, R. J., Galvin, A. B. et al.: 1998, J. Geophys. Res. 103, 14587.
Neugebauer, M., Liewer, P. C., Smith, E. J., Skoug, R. M., and Zurbuchen, T. H.: 2002, J. Geophys. Res., in press.
Parker, E. N.: 1958, Astrophys. J. 128, 669.
Schatten, K. H., Wilcox, J. M., and Ness, N. F.: 1969, Solar Phys. 6, 442.
Schrijver, C. J.: 2001, Astrophys. J. 547, 475.
Schrijver, C. J. and Title, A. M.: 2001, Astrophys. J. 551, 1099.
Schrijver, C. J., DeRosa, M. L., and Title, A. M.: 2002, Astrophys. J. 577, 1006.
Schrijver, C. J., Shine, R. A., Hagenaar, H. J., Hurlburt, N. E., Title, A. M., Strous, L. H., Jefferies, S. M., Jones, A. R., Harvey, J. W., and Duvall, T. L: 1996, Astrophys. J. 468, 921.
Schrijver, C. J., Title, A. M., Berger, T. E., Fletcher, L., Hurlburt, N. E., Nightingale, R., Shine, R. A., Tarbell, T. D., Wolfson, J., Golub, L., Bookbinder, J. A., DeLuca, E. E., McMullen, R. A., Warren, H. P., Kankelborg, C. C., Handy, B. N., and De Pontieu, B.: 1999, Solar Phys. 187, 261.
Schwenn, R., Inhester, B., Plunkett, S. P. et al.: 1997, Solar Phys. 175, 667.
Sheeley, N. R., Nash, A. G., and Wang, Y.-M.: 1987, Astrophys. J. 319, 481.
Sheeley, N. R., Wang, Y.-M., and Nash, A. G.: 1992, Astrophys. J. 401, 378.
Sheeley, N. R., Bohlin, J. D., Brueckner, G. E., Purcell, J. D., Scherrer, V. S., and Tousey, R.: 1975, Solar Phys. 40, 103.
Švestka, Z., Solodyna, C. V., Howard, R., and Levine, R. H.: 1977, Solar Phys. 55, 359.
Von Steiger, R., Geiss, J., and Gloeckler, G.: 1997, in J. R. Jokipii, C. P. Sonnett, and M. S. Giampapa (eds.), Cosmic Winds and the Heliosphere, University of Arizona Press, Tucson, Arizona, p. 581.
Von Steiger, R., Schwadron, N., Fisk, L., Geiss, J., Gloeckler, G., Hefti, S., Wilken, B., Wimmer-Schweingruber, R., and Zurbuchen, T.: 2000, J. Geophys. Res. 105, 27217.
Waldmeier, H.: 1957, Die Sonnenkorona III, Birkhäuser Verlag, Basel.
Wang, H., Yan, Y., Sakurai, T., and Zhang, M.: 2000, Solar Phys. 197, 263.
Wang, Y.-M. and Sheeley, N. R.: 1990a, Astrophys. J. 355, 726.
Wang, Y.-M. and Sheeley, N. R.: 1990b, Astrophys. J. 365, 372.
Wang, Y.-M. and Sheeley, N. R.: 1991, Astrophys. J. 375, 761.
Wang, Y.-M. and Sheeley, N. R.: 1992, Astrophys. J. 392, 310.
Wang, Y.-M. and Sheeley, N. R.: 1993, Astrophys. J. 414, 916.
Wang, Y.-M. and Sheeley, N. R.: 1994, Astrophys. J. 430, 399.
Wang, Y.-M. and Sheeley, N. R.: 1995, Astrophys. J. Lett. 447, 143.
Wang, Y.-M. and Sheeley, N. R.: 2002, J. Geophys. Res., in press.
Wang, Y.-M., Lean, J., and Sheeley, N. R.: 2000, Geophys. Res. Lett. 27, 505.
Wang, Y.-M., Nash, A. G., and Sheeley, N. R.: 1989, Astrophys. J. 347, 529.
Wang, Y.-M., Sheeley, N. R., and Lean, J.: 2000, Geophys. Res. Lett. 27, 621.
Wilson, P. R., Altrock, R. C., Harvey, K. L., Martin, S. F., and Snodgrass, H. B.: 1988, Nature 333, 748.
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Schrijver, C.J., DeRosa, M.L. Photospheric and heliospheric magnetic fields. Sol Phys 212, 165–200 (2003). https://doi.org/10.1023/A:1022908504100
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DOI: https://doi.org/10.1023/A:1022908504100