Authors: Eiichi Sasaki, Shin-ichi Takehiro, Michio Yamada

Abstract:

We study bifurcation structure of the zonal jet flow the streamfunction of which is expressed by a single spherical harmonics on a rotating sphere. In the non-rotating case, we find that a steady traveling wave solution arises from the zonal jet flow through Hopf bifurcation. As the Reynolds number increases, several traveling solutions arise only through the pitchfork bifurcations and at high Reynolds number the bifurcating solutions become Hopf unstable. In the rotating case, on the other hand, under the stabilizing effect of rotation, as the absolute value of rotation rate increases, the number of the bifurcating solutions arising from the zonal jet flow decreases monotonically. We also carry out time integration to study unsteady solutions at high Reynolds number and find that in the non-rotating case the unsteady solutions are chaotic, while not in the rotating cases calculated. This result reflects the general tendency that the rotation stabilizes nonlinear solutions of Navier-Stokes equations.

Keywords: rotating sphere, two-dimensional flow, bifurcationstructure

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1334764

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References:

[1] P. G. Williams, Planetary circulations: 1. Barotropic representation of Jovian and Terrestrial turbulence J. Atmos. Sci., 35, 1399-1426, 1978.
[2] S. Yoden, S. and M. Yamada, A numerical experiment on twodimensional Decaying turbulence on a rotating sphere. J. Atmos. Sci., 50, 631-643, 1993.
[3] S. Takehiro, S., M. Yamada and Y-Y. Hayashi, Circumpolar jets emerging in two-dimensional non-divergent decaying turbulence on a rapidly rotating sphere. Fluid Dyn. Res., 39, 209-220, 2007.
[4] T. Nozawa and S. Yoden, Formation of zonal band structure in forced two-dimensional turbulence on a rotating sphere, Phys. Fluid , 9, 2081- 2093, 1997.
[5] K. Obuse, S. Takehiro and M. Yamada, Long-time asymptotic states of forced two-dimensional barotropic incompressible flows on a rotating sphere. Phys. Fluid, 22, 056601, 2010.
[6] BAINES, P. G., 1976 The stability of planetary waves on a sphere. J. Fluid Mech. 73-2, 193-213.
[7] E. Sasaki, S. Takehiro, and M, Yamada, A note on the stability of inviscid zonal jet flows on a rotating sphere, J. Fluid Mech., 710, 154-165, 2012.
[8] E. Sasaki, S. Takehiro and M. Yamada, Stability of two-dimensional viscous zonal jet flows on a rotating sphere, in preparation.
[9] I. V. Iudovisch, Example of the generation of a secondary stationary or periodic flow when there is loss of stability of the laminar flow of a viscous incompressible fluid. J. Appl. Math. Mech., 29, 527-544, 1965.
[10] D. L. Meshalkin and Y. G. Sinai, 1962 Investigation of the stability of a stationary solution of a system of equations for the plane movement of an incompressible viscous liquid, J. Appl. Math. and Mech., 25, 1700- 1705, 1962
[11] H. Okamoto and M. Sh¯oji, Bifurcation Diagrams in Kolmogorov-s Problem of Viscous Incompressible Fluid on 2-D Flat Tori. Japan J. Indus Appl. Math., 10, 191-218, 1993.
[12] C. S. Kim, S. C. and H. Okamoto, Stationary vortices of large scale appearing in 2D Navier-Stokes equations at large Reynolds numbers. Japan J. Indust. Appl. Math., 27, 47-71, 2010.
[13] N. Platt, L. Sirovich and N. Fitzmaurice, An investigation of chaotic Kolmogorov flows. Phys. Fluid , 3, 681-696, 1991.
[14] M. Inubushi, M. U. Kobayashi, S. Takehiro and M. Yamada, Covariant Lyapunov analysis of chaotic Kolmogorov flows. Phys. Rev. E 85, 016331, 2012.
[15] I. Silberman, Planetary waves in the atmosphere, J. Meteo., 11, 27-34, 1953.
[16] E. Sasaki, S. Takehiro and M. Yamada, Bifurcation structure of twodimensional viscous zonal jet flows on a rotating sphere, in preparation.
[17] K Ishioka, ispack-0.96, http://www.gfd-dennou.org/arch/ispack/, GFD Dennou Club, 2011.
[18] S. Takehiro, Y. SASAKI, Y. Morikawa, K. Ishioka, M. Odaka, O. Y. Takahashi, S. Nishizawa, K. Nakajima, M. Ishiwatari, and Y.-Y, Hayashi, SPMODEL Development Group, Hierarchical Spectral Models for GFD (SPMODEL), http://www.gfd-dennou.org/library/ spmodel/, GFD Dennou Club, 2011.