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Numerical Functional Analysis and Optimization Volume 28, 2007 - Issue 7-8
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Original Articles

Finite Dimensional Behaviors of the Primitive Equations Under Small Depth Assumption

Changbing Hu Department of Mathematics, Missouri State University, Springfield, Missouri, USACorrespondence[email protected]
Pages 853-882 | Published online: 13 Aug 2007

REFERENCES

  • C. Cao and E. Titi ( 2007 ). Global well-posedness of three dimensional viscous primitive equations of large scale ocean and atmosphere dynamics, arXiv: Math. AP/0503028 v2 16 Nov 2005. To appear in Ann. Math. 165 .
  • C. Foias and G. Prodi ( 1967 ). Sur le comportement global des solutions non stationnaries des equations de Navier–Stokes en dimension two . Rend. Sem. Mat. Univ. Padova 39 : 1 – 34 .
  • C. Foias , O. Manley , R. Temam , and Y. Treve ( 1983 ). Asymptotic analysis of the Navier–Stokes equations . Physica D 9 : 157 – 188 .
  • C. Foias and R. Temam ( 1984 ). Determing the solutions of the Navier–Stokes equations by a set of nodal values . Math. Comp. 43 : 177 – 183 .
  • C. Foias and E. Titi ( 1991 ). Determining nodes, finite difference schemes, and inertial manifolds . Nonlinearity 4 : 133 – 153 .
  • C. Hu ( 2005 ). Asymptotic analysis of the primitive equations under small depth assumption . Nonlinear Anal. A 61 : 425 – 460 .
  • C. Hu , R. Temam , and M. Ziane ( 2002 ). Regularity results for GFD-Stokes problem and some related linear elliptic PDEs in primitive equations . Chinese Ann. Math. 23B : 277 – 292 .
  • C. Hu , R. Temam , and M. Ziane ( 2003 ). The primitive equations on the large scale ocean under small depth hypothesis . Disc. Cont. Dyn. Syst. 9 ( 1 ): 97 – 131 .
  • G. Haltiner and R. Williams ( 1980 ). Numerical Weather Prediction and Dynamic Meteorology. , 2nd ed . Wiley , New York .
  • N. Ju ( 2000 ). Estimates of asymptotic degrees of freedom for solutions to the Navier–Stokes equations . Nonlinearity 13 : 777 – 789 .
  • N. Ju ( 2007 ). The global attractor for the solutions to the 3D viscous primitive equations . Discrete and Continuous Dynamical Systems 17 : 159 – 179 .
  • D. Jones and E. Titi ( 1992 ). Determining finite volume elements for the 2D Navier–Stokes equations . Physica D 60 : 117 – 133 .
  • D. Jones and E. Titi ( 1992 ). On the number of determining nodes for the 2D Navier–Stokes equations . J. Math. Anal. Appl. 168 : 72 – 88 .
  • G. Kobelkov ( 2006 ). Existence of a solution “in whole” for the large scale ocean dynamics equations . Comptes Rendus Acad. Sci. Paris 343 : 283 – 286 .
  • R. Kraichnan ( 1967 ). Inertial ranges in two-dimensional turbulence . Phys. Fluid 10 : 1417 – 1423 .
  • O.A. Ladyzhenskaya ( 1969 ). The Mathematical Theory of Viscous Incompressible Flow. , 2nd ed . Gordon and Breach : New York .
  • L. Landau and E. Lipschitz ( 1959 ). Fluid Mechanics . Reading , MA : Addison-Wesley .
  • J. L. Lions , R. Temam , and S. Wang ( 1992 ). New formulation of the primitive equations of the atmosphere and applications . Nonlinearity 5a : 237 – 288 .
  • J. L. Lions , R. Temam , and S. Wang ( 1992 ). On the equations of the large scale ocean . Nonlinearity 5b : 1007 – 1053 .
  • J. L. Lions , R. Temam , and S. Wang ( 1993 ). Models of the coupled atmosphere and ocean (CAO I) . Computation Mechanics Advances 1a : 5 – 54 .
  • J. Pedlosky ( 1987 ). Geophysical Fluid Dynamics. , 2nd ed . Springer-Verlag , New York .
  • R. Temam ( 2001 ). Navier-Stokes Equations, Theory and Numerical Analysis, , 3rd revised ed . North Holland, Amsterdam; reprinted in the AMS Chelsea series, AMS, Providence, RI .
  • R. Temam ( 1997 ). Infinite Dimensional Dynamical Systems in Mechanics and Physics. , 2nd ed . Applied Math. Sci. 68 . Springer , New York .
  • R. Temam and M. Ziane ( 1996 ). Navier–Stokes equations in three dimensional thin domains with various boundary conditions . Advances in Differential Equations 1 : 499 – 546 .
  • R. Temam and M. Ziane ( 1996 ). Navier-Stokes equations in thin spherical shells . Contemporary Mathematics 209 : 281 – 314 .
  • R. Temam and M. Ziane ( 2004 ). Some mathematical problems in geophysical fluid dynamics . In: Handbook of Mathematical Fluid Dynamics , vol. III . North-Holland , Amsterdam , pp. 535 – 657 .
  • W.M. Washington and C.L. Parkinson ( 1986 ). Introduction to Three-Dimensional Climate Modeling . Oxford University Press , Oxford .

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