Abstract
The 2D horizontal velocity field determined from local correlation tracking of granulation and its divergence have remarkably different appearances. The 2D horizontal velocity shows the classical 32 Mm supergranular cellular outflow bounded by the chromospheric network, whereas the divergence is dominated by distinct long-lived sources and sinks of about 7 Mm size. The 2D horizontal velocity shows no obvious evidence for ≈7 Mm cells, and the divergence exhibits little power with the ≈32 Mm scale. However, by mass continuity for a steady 3D flow in a stratified atmosphere, the divergence of the 2D horizontal component is equal to the vertical velocity divided by a height scale. Thus the 3D steady solar flow field at the bottom of the photosphere has a vertical component consisting primarily of ≈7 Mm sources and sinks, which define the 2D cellular-like ≈32 Mm continuous horizontal outflows.
Simultaneous Doppler vertical velocity measurements verify the mass-continuity relation, and give a height scale equal to the density scale height in the photosphere within observational error. The observational result is consistent with our theoretical expectation. Any height scale other than the density scale height would indicate a vertical velocity thate-folds on a scale comparable to or smaller than the density scale height, which we argue is unphysical near the top of the convection zone. The continuity relation indicates that vortex-free steady horizontal velocities seen at the solar surface, i.e., the horizontal supergranular flow, must diminish with depth due to the increasing density scale height. We estimate that the horizontal supergranular flow cannot extend much more than onee-fold increase in the density scale height below the visible solar surface, about 2.4 Mm. Therefore the convection below the solar surface should be characterized by the scale of the principal steady vertical velocity component, i.e., by vertical plumes having a dimension of ≈7 Mm - what we have called ‘mesogranulation’ - rather than closed ≈32 Mm cells as is widely believed.
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References
Ambrož, P.: 1992, in K. Harvey (ed.),The Solar Cycle, ASP Conference Series 27, 35.
Bevington, P. R.: 1969,Data Reduction and Error Analysis for the Physical Sciences, McGraw-Hill Inc., New York.
Bogart, R. S., Ferguson, S. H., Scherrer, P. H., Tarbell;, T. D., and Title, A. M.: 1988,Solar Phys. 116, 205.
Brandt, P. N., Ferguson, S., Scharmer, G. B., Shine, R. A., Tarbell, T. D., Title, A. M., and Topka, K.: 1991,Astron. Astrophys. 241, 219.
Chou, D.-Y., Chen, C.-S., Ou, K.-T., and Wang, C.-C.: 1992,Astrophys. J. 396, 333.
Darvann, T. A.: 1989, in O. von der Lühe (ed.),High Spatial Resolution Solar Observations, Proceedings of the Tenth Sacramento Peak Summer Symposium, Sunspot, New Mexico, 22–26 August, 1988, p. 502.
Darvann, T. A.: 1991, ‘Solar Horizontal Flows and Differential Rotation Determined by Local Correlation Tracking of Granulation’, C.S. Thesis, University of Oslo.
Darvann, T. A., Koutchmy, S., and Zirker, J. B.: 1989,Hvar Obs. Bull. 13, 243.
Dunn, R. B. and November, L. J.: 1985, in R. Muller (ed.),High Resolution in Solar Physics, Lecture Notes in Physics 233, 85, Springer-Verlag, New York.
Hart, A. B.: 1954,Monthly Notices Roy. Astron. Soc. 114, 17.
Hart, A. B.: 1956,Monthly Notices Roy. Astron. Soc. 116, 38.
Harvey, J. W.: 1965,Publ. Astron. Soc. Pacific 77, 129.
Hathaway, D. H.: 1992,Solar Phys. 137, 15.
Hathaway, D. H., Rhodes, E. J., Jr., Cacciani, A., and Korzennik, S. G.: 1991, in D. Gough and J. Toomre (eds.),Proceedings of the Conference on Challenges to Theories of the Structure of Moderate Mass Stars, Conference Proceedings, Santa Barbara CA, June 19–22, 1990,Lecture Notes in Physics 388, 163.
Kawaguchi, I.: 1980,Solar Phys. 65, 207.
Koutchmy, S. and Lebecq, C.: 1986,Astron. Astrophys. 169, 323.
Kuhn, J. R.: 1983,Astrophys. J. 264, 689.
Leighton, R. B., Noyes, R. W., and Simon, G. W.: 1962,Astrophys. J. 135, 474.
Lin, H. and Kuhn, J. R.: 1992,Solar Phys. 141, 1.
Massaguer, J. M., Latour, J., Toomre, J., and Zahn, J.-P.: 1984,Astron. Astrophys. 140, 1.
Mitchell, W. E., Jr.: 1982,Solar Phys. 80, 3.
November, L. J.: 1984, in S.. L. Keil (ed.),Small Scale Dynamical Processes in Quiet Stellar Atmospheres, Sacramento Peak Observatory Proceedings, 25–29 July, 1983, p. 74.
November, L. J.: 1986,Appl. Optics 25, 392.
November, L. J.: 1989a, in O. von der Lühe (ed.),High Spatial Resolution Solar Observations, Proceedings of the Tenth Sacramento Peak Summer Symposium, Sunspot, New Mexico, 22–26 August, 1988, p. 457.
November, L. J.: 1989b,Astrophys. J. 344, 494.
November, L. J.: 1994, in K. S. Balasubramaniam and G. W. Simon (eds.),Solar Active Region Evolution - Comparing Models with Observations, Proceedings of the Fourteenth Sacramento Peak Summer Symposium, Sunspot, New Mexico, August 30 to September 3, 1993.
November, L. J. and Simon, G. W.: 1988,Astrophys. J. 333, 427.
November, L. J. and Wilkins, L. M.: 1992, AFGL Technical Report PL-TR-92-2246.
November, L. J., Toomre, J., Gebbie, K. B., and Simon, G. W.: 1981,Astrophys. J. 245, L123.
November, L. J., Toomre, J., Gebbie, K. B., and Simon, G. W.: 1982,Astrophys. J. 258, 846.
November, L. J., Simon, G. W., Tarbell, T. D., Title, A. M., and Ferguson, S. H.: 1987, in R. G. Athay (ed.),Proceedings 2nd Workshop on Theoretical Problems in High-Resolution Solar Physics, NASA Conference Publ. 2483, p. 121.
Oda, N.: 1989,Solar Phys. 93, 243.
Ramsey, H. E., Schoolman, S. A., and Title, A. M.: 1977,Astrophys. J. 140, 1120.
Simon, G. W.: 1967,Z. Astrophys. 65, 345.
Simon, G. W. and Weiss, N. O.: 1992,Monthly Notices Roy. Astron. Soc. 252, 1P.
Simon, G. W., Title, A. M., Topka, K. P., Tarbell, T. D., Shine, R. A., Ferguson, S. H., Zirin, H., and the SOUP Team: 1988,Astrophys. J. 327, 964.
Simon, G. W., Brandt, P. B., November, L. J., Scharmer, G. B., and Shine, R. A.: 1994, in R. J. Rutten (ed.),Solar Surface Magnetism, Soesterberg Meeting, 1–5 November, 1993.
Spruit, H. C.: 1977, ‘Magnetic Flux Tubes and Transport of Heat in the Convection Zone of the Sun’, Thesis, Utrecht.
Spruit, H. C., Nordland, Å, and Title, A. M.: 1990,Ann. Rev. Astron. Astrophys. 28, 263.
Stein, R. F. and Nordland, Å: 1989,Astrophys. J. 342, L95.
Strauss, Th., Deubner, F. L., and Fleck, B.: 1992,Astron. Astrophys. 256, 652.
Title, A. M., Tarbell, T. D., Simon, G. W., and the SOUP Team: 1986,Adv. Space Res. 6, 253.
Title, A. M., Tarbell, T. D., Topka, K. P., Ferguson, S. H., Shine, R. A., and the SOUP Team: 1989,Astrophys. J. 336, 475.
Wang, H. and Zirin, H.: 1989, in O. von der Lühe (ed.),High Spatial Resolution Solar Observations, Proceedings of the Tenth Sacramento Peak Summer Symposium, Sunspot, New Mexico, 22–26 August, 1988, p. 491.
Worden, S. P. and Simon, G. W.: 1976,Solar Phys. 46, 73.
Zwaan, C.: 1987,Ann. Rev. Astron. Astrophys. 25, 83.
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November, L.J. Inferring the depth extent of the horizontal supergranular flow. Sol Phys 154, 1–17 (1994). https://doi.org/10.1007/BF00676773
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DOI: https://doi.org/10.1007/BF00676773