Иркутск, Россия
сотрудник
Иркутск, Россия
Иркутск, Россия
The first part of the work presents the results of numerical experiments with the magnetohydrodynamic model of “shallow water” to assess the degree of influence of the magnetic field on the development of instabilities conditioned by a combination of inhomogeneities in the mean flow and the mean magnetic field. Normal mode calculations have confirmed the earlier obtained result on the different influence of weak and strong magnetic fields on the instability of differential rotation. Calculations have shown that a weak magnetic field stabilizes the development of instabilities, whereas a strong magnetic field, on the contrary, enhances the instability. Azimuthal inhomogeneities of differential rotation in all cases contribute to the development of instabilities. In the second part of the work, we examine the spatial structure of normal modes and make an attempt to interpret the torsional oscillations observed in the atmospheres of Earth and the Sun. Calculations have shown that regular axisymmetric disturbances can be caused by the formation of a cyclonic vortex above the pole, which is characteristic of Earth's atmosphere and, possibly, of the Sun's atmosphere. The least damped normal mode of a stable polar cyclone has a structure of torsional oscillations. Flow anomalies and the development of an anticyclonic eddy in winter at midlatitudes destroy torsional oscillations and lead to a rapid amplification of normal modes, which are more complex in structure.
hydrodynamics, atmosphere, normal modes, magnetic field, torsional oscillations
1. Altrock R., Howe R., Ulrich R. Solar torsional oscillations and their relationship to coronal activity. American Astronomical Society, SPD Meeting, BAAS 38. 2006, vol. 38, p. 258. http://adsabs.harvard.edu/cgi-bin/nph-bib_query?bibcode=2006SPD....37.3203A.
2. Branstator G., Held I. Westward Propagating Normal modes in the presence of stationary background waves. J. Atmos. Sci. 1995, vol. 52, pp. 247-262.
3. Bumba V. Large-scale magnetic fields on the Sun. Solar activity Problems. Мoscow, Mir Publ., 1979, pp. 50-74. (In Russian).
4. Bumba V., Howard R. Large-scale distribution of solar magnetic fields. Astrophys. J. 1965, vol. 141, no. 4, pp. 1502-1512.
5. Bumba V., Makarov V. Background magnetic fields on the Sun. Solar Magnetic Fields. I. Corona: Proc. ХIII Consultative Conference on Solar Physics. Novosibirsk, Nauka Publ., 1989, vol. 1, pp. 51-71. (In Russian).
6. Cally P.S., Dikpati M., Gilman P.A. Three-dimensional magnetoshear instabilities in the solar tachocline. Monthly Notices of the Royal Astron. Soc. Papers. 2003, vol. 339, iss. 4, pp. 957-972.
7. Danilov S.D., Gurarii D. Quasi two-dimensional turbulence. Physics-Uspekhi. 2000, vol. 170, iss. 9, pp. 921-969.
8. Dikpati M., Gilman P.A. Analysis of hydrodynamic stability of solar tachocline latitudinal differential rotation using a shallow-water model. Astrophys. J. Papers. 2001, vol. 551, pp. 536-564. DOI:https://doi.org/10.1086/320080.
9. Dikpati M., Gilman P.A. A Shallow-water theory for the Sun’s active longitudes. Astrophys. J. 2005, vol. 635, iss. 2, pp. L193-L196.
10. Dymnikov V., Filatov A. Sustainability of large-scale atmospheric processes. Computing Mathematics Department AS USSR. Мoscow, 1988, pp.1-140. (In Russian).
11. Dymnikov V., Skiba Yu. Barotropic instability of zonal asymmetric atmospheric flows. Computing Processes and Systems. Iss. 4. Moscow, Nauka Publ., 1986, pp. 63-104. (In Russian).
12. Fournier D., Gizon L., Hyest L. Viscous inertial modes on a differentially rotating sphere: Comparison with solar observations. Astron. Astrophys. 2022, vol. 664, pp. 1-16. DOI:https://doi.org/10.1051/0004-6361/202243473.
13. Gill А. Dynamics of atmosphere and ocean. In 2 vol. Мoscow, Mir Publ., 1986, vol. 2, 415 p.
14. Gilman P.A. Stability of baroclinic flows in a zonal magnetic field. Part 1-3. J. Atmos. Sci. 1967, vol. 24, no. 2, pp. 101-143.
15. Gilman P.A., Fox P.A. Joint instability of latitudinal differential rotation and toroidal magnetic fields below the solar convection zone. Astrophys. J. 1997, vol. 484, no. 1, pp. 439-454.
16. Gilman P.A., Dikpati M., Miesch M.S. Global MHD instabilities in a three-dimensional Thin-Shell Model of solar tachocline. Astrophys. J. Suppl. Ser. Papers. 2007, vol. 170, pp. 203-227. DOI:https://doi.org/10.1086/512016.
17. Kitchatinov L.L., Rüdiger G. Stability of latitudinal differential rotation in stars. Astron. Astrophys. 2009, vol. 504, no. 2, pp. 303-307.
18. Large-Scale Dynamic Processes in the Atmosphere. Мoscow, Mir Publ., 1988, 430 p. (In Russian).
19. Marchuk G., Agoshkov V., Shutyaev V. Adjoint Equations and Perturbation Algorithms in Applied Problems. Computing Processes and Systems. Мoscow, Nauka Publ., 1986, 272, pp. 5-62. (In Russian).
20. Miesch M.S. Large-scale dynamics of the convection zone and tachocline. Living Reviews in Solar Physics. 2005. Vol. 2, no. 1. P. 1-139.
21. Mishin V., Tomozov V. Manifestations of Kelvin-Helmholtz instability in the solar atmosphere, solar wind and Earth's magnetosphere. Solar-Terr. Phys. 2014, iss. 25, pp. 10-20. (In Russian).
22. Mordvinov V.I., Zorkaltseva O.S. Normal Mode as a Cause of Large-Scale Variations in the Troposphere and Strato-sphere. Izvestiya, Atmospheric and Oceanic Phys. 2022, vol. 58, no. 2, pp. 140-149.
23. Mordvinov V., Devyatova E., Tomozov V. Hydrodynamic instabilities in a tachocline due to layer thickness variations. Solar-Terr. Phys. 2012, iss. 20, pp. 3-8. (In Russian).
24. Mordvinov V., Devyatova E., Tomozov V. Hydrodynamic instabilities in the tachocline due to layer thickness variations and mean flow inhomogeneities. Solar-Terr. Phys. 2013, iss. 23, pp. 3-12. (In Russian).
25. Mordvinov V., Latysheva I. General circulation theory of the atmosphere, variability of large-scale motions. Irkutsk, izdatelstvo IGU, 2013, 193 p. (In Russian).
26. Mordvinov V.I, Olemskoy S.V., Latyshev S.V. Influence of mean magnetic field and magnetic field of the velocity disturbances on the development of hydrodynamic instabilities in tachocline. Proc. SPIE 11208, 25th International Symposium on Atmospheric and Ocean Optics: Atmospheric Physics, 1120803 (18 December 2019). 2019. DOI:https://doi.org/10.1117/12.2538285.
27. Tikhomolov E.M. Large-scale vortical flows and penetrative convection in the Sun. Nuclear Physics A. 2005, vol. 758, no. 1. pp. 709-712.
28. Zorkaltseva O.S., Mordvinov V.I., Devyatova E.V., Dombrovskaya N.S. Method For Calculating Torsional Oscillations in Earth’s Atmosphere from NCEP/NCAR, MERRA-2, ECMWF ERA-40, AND ERA-INTERIM. Solar-Terr. Phys. 2019, vol. 5, iss. 1, pp. 69-76. DOI:https://doi.org/10.12737/stp51201910.