Mathematical Analysis of the Jin-Neelin Model of El Niño-Southern-Oscillation

Yining Cao , Mickaël D. Chekroun , Aimin Huang , Roger Temam

Chinese Annals of Mathematics, Series B ›› 2019, Vol. 40 ›› Issue (1) : 1 -38.

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Chinese Annals of Mathematics, Series B ›› 2019, Vol. 40 ›› Issue (1) : 1 -38. DOI: 10.1007/s11401-018-0115-3
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Mathematical Analysis of the Jin-Neelin Model of El Niño-Southern-Oscillation

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Abstract

The Jin-Neelin model for the El Niño–Southern Oscillation (ENSO for short) is considered for which the authors establish existence and uniqueness of global solutions in time over an unbounded channel domain. The result is proved for initial data and forcing that are sufficiently small. The smallness conditions involve in particular key physical parameters of the model such as those that control the travel time of the equatorial waves and the strength of feedback due to vertical-shear currents and upwelling; central mechanisms in ENSO dynamics.

From the mathematical view point, the system appears as the coupling of a linear shallow water system and a nonlinear heat equation. Because of the very different nature of the two components of the system, the authors find it convenient to prove the existence of solution by semi-discretization in time and utilization of a fractional step scheme. The main idea consists of handling the coupling between the oceanic and temperature components by dividing the time interval into small sub-intervals of length k and on each sub-interval to solve successively the oceanic component, using the temperature T calculated on the previous sub-interval, to then solve the sea-surface temperature (SST for short) equation on the current sub-interval. The passage to the limit as k tends to zero is ensured via a priori estimates derived under the aforementioned smallness conditions.

Keywords

El Niño–Southern Oscillation / Coupled nonlinear hyperbolic-parabolic systems / Fractional step method / Semigroup theory

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Yining Cao, Mickaël D. Chekroun, Aimin Huang, Roger Temam. Mathematical Analysis of the Jin-Neelin Model of El Niño-Southern-Oscillation. Chinese Annals of Mathematics, Series B, 2019, 40(1): 1-38 DOI:10.1007/s11401-018-0115-3

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Adams R. A., Fournier J. J. F.. Sobolev Spaces, 2003
[2]

Aubin J.P.. Un théoreme de compacité. C. R. Acad. Sci. Paris, 1963, 256(24): 5042-5044
[3]

Barnston A. G., Tippett M. K., Heureux M. L. Skill of real–time seasonal ENSO model predictions during 2002–2011 — is our capability improving?. Bull. Amer. Meteo. Soc., 2012, 93(5): 631-651

[4]

Bjerknes J.. Atmospheric teleconnections from the equatorial Pacific. Monthly Weather Review, 1969, 97(3): 163-172

[5]

Brézis H.. Functional Analysis, 2011
[6]

Camargo S. J., Sobel A. H.. Western North Pacific tropical cyclone intensity and ENSO. Journal of Climate, 2005, 18(15): 2996-3006

[7]

Cane M. A., Zebiak S. E.. A theory for El Nieno and the Southern Oscillation. Science, 1985, 228: 1085-1088

[8]

Cane M. A.. Experimental forecasts of El Nieno. Nature, 1986, 321: 827-832

[9]

Cane M. A., Sarachik E. S.. Forced baroclinic ocean motions, II, The linear equatorial bounded case. J. of Marine Research, 1977, 35(2): 395-432
[10]

Cao C., Titi E. S.. Global well–posedness of the three–dimensional viscous primitive equations of large scale ocean and atmosphere dynamics. Ann. Math. (2), 2007, 166(1): 245-267

[11]

Cazenave T., Haraux A.. An Introduction to Semilinear Evolution Equations, 1998
[12]

Chang P., Ji L., Wang B., Li T.. Interactions between the seasonal cycle and El Nieno–Southern Oscillation in an intermediate coupled ocean–atmosphere model. Journal of the Atmospheric Sciences, 1995, 52(13): 2353-2372

[13]

Chekroun M. D., Ghil M., Neelin J. D.. Pullback attractor crisis in a delay differential ENSO model, 2018

[14]

Chekroun M. D., Kondrashov D., Ghil M.. Predicting stochastic systems by noise sampling, and application to the El Nieno–Southern Oscillation. Proc. Natl. Acad. Sci USA, 2011, 108(29): 11766-11771

[15]

Chekroun M. D., Neelin J. D., Kondrashov D. Rough parameter dependence in climate models: The role of Ruelle–Pollicott resonances. Proc. Natl. Acad. Sci USA, 2014, 111(5): 1684-1690

[16]

Chekroun M. D., Simonnet E., Ghil M.. Stochastic climate dynamics: Random attractors and timedependent invariant measures. Physica D., 2011, 240(21): 1685-1700

[17]

Chen C., Cane M. A., Henderson N. Diversity, nonlinearity, seasonality, and memory effect in ENSO simulation and prediction using empirical model reduction. Journal of Climate, 2016, 29(5): 1809-1830

[18]

Chorin A.. Numerical solution of the Navier–Stokes equations. Math. Comput., 1968, 22: 745-762

[19]

Coti Zelati M.. Huang, A., Kukavica, I., et al., The primitive equations of the atmosphere in presence of vapour saturation. Nonlinearity, 2015, 28(3): 625-668

[20]

Dijkstra H. A.. Nonlinear Physical Oceanography: A Dynamical Systems Approach to the Large Scale Ocean Circulation and El Nieno, 2005
[21]

Engel K.J., Nagel R.. One–Parameter Semigroups for Linear Evolution Equations, 2000
[22]

Guilyardi E., Wittenberg A., Fedorov A. Understanding El Nieno in ocean–atmosphere general circulation models: Progress and challenges. Bulletin of the American Meteorological Society, 2009, 90(3): 325-340

[23]

Huang A., Temam R.. The linearized 2D inviscid shallow water equations in a rectangle: Boundary conditions and well–posedness. Archive for Rational Mechanics and Analysis, 2014, 211(3): 1027-1063

[24]

Huang A., Temam R.. The nonlinear 2D subcritical inviscid shallow water equations with periodicity in one direction. Commun. Pure Appl. Anal., 2014, 13(5): 2005-2038

[25]

Huang A., Temam R.. The linear hyperbolic initial and boundary value problems in a domain with corners, Discrete and Continuous Dynamical Systems. Series B, 2014, 19(6): 1627-1665
[26]

Huang A., Temam R.. The 2D nonlinear fully hyperbolic inviscid shallow water equations in a rectangle. J. Dynam. Differential Equations, 2015, 27(3–4): 763-785

[27]

Jin F.F.. An equatorial ocean recharge paradigm for ENSO, Part I: Conceptual model. Journal of the Atmospheric Sciences, 1997, 54(7): 811-829

[28]

Jin F.F., Neelin J. D.. Modes of interannual tropical ocean–atmosphere interaction–A unified view, Part I: Numerical results. Journal of the Atmospheric Sciences, 1993, 50(21): 3477-3503

[29]

Jin F.F., Neelin J. D.. Modes of interannual tropical ocean–atmosphere interaction–A unified view, Part III: Analytical results in fully coupled cases. Journal of the atmospheric sciences, 1993, 50(21): 3523-3540

[30]

Jin F.F., Neelin J. D., Ghil M.. El Nieno on the Devil’s staircase: Annual subharmonic steps to chaos. Science, 1994, 274: 70-72

[31]

Jin F.F., Neelin J. D., Ghil M.. El Nieno/Southern Oscillation and the annual cycle: Subharmonic frequency locking and aperiodicity. Physica D, 1996, 98: 442-465

[32]

Reviews of Geophysics, 2009, 47 2
[33]

Kirtman B. P., Schopf P. S.. Decadal variability in ENSO predictability and prediction. Journal of Climate, 1998, 11(11): 2804-2822

[34]

Kobelkov G. M.. Existence of a solution “in the large” for ocean dynamics equations. J. Math. Fluid Mech., 2007, 9(4): 588-610

[35]

Kondrashov D., Kravtsov S., Robertson A. W., Ghil M.. A hierarchy of data–based ENSO models. J. Climate, 1995, 18(21): 4425-4444

[36]

Kukavica I., Ziane M.. The regularity of solutions of the primitive equations of the ocean in space dimension three. C. R. Math. Acad. Sci. Paris, 2007, 345(5): 257-260

[37]

Lions J. L.. Quelques méthodes de résolution des problèmes aux limites non linéaires, 1969
[38]

Lions J. L., Magenes E.. Non–homogeneous Boundary Value Problems and Applications., 1972

[39]

Lions J.L., Temam R., Wang S.. New formulations of the primitive equations of atmosphere and applications. Nonlinearity, 1992, 5(2): 237-288

[40]

Lions J.L., Temam R., Wang S.. On the equations of the large–scale ocean. Nonlinearity, 1992, 5(5): 1007-1053

[41]

Lyon B., Barnston A. G.. ENSO and the spatial extent of interannual precipitation extremes in tropical land areas. Journal of Climate, 2005, 18(23): 5095-5109

[42]

Marchuk G. I.. Methods of Numerical Mathematics, 1982

[43]

Matsuno T.. Quasi–geostrophic motions in the equatorial area, Journal of the Meteorological Society of Japan.. Ser. II, 1966, 44(1): 25-43
[44]

McCreary J. P. Jr Anderson D. L. T.. A simple model of El Nieno and the Southern Oscillation. Monthly Weather Review, 1984, 112(5): 934-946

[45]

McCreary J. P. Jr Anderson D. L. T.. Simple models of El Nieno and the Southern Oscillation, in Elsevier oceanography series, 1985 345-370
[46]

McCreary J. P. Jr Anderson D. L. T.. An overview of coupled ocean–atmosphere models of El Nieno and the Southern Oscillation. Journal of Geophysical Research: Oceans, 1991, 96(S01): 3125-3150

[47]

McPhaden M. J., Zebiak S. E., Glantz M. H.. ENSO as an integrating concept in earth science. science, 2006, 314(5806): 1740-1745

[48]

Mechoso C. R., Neelin J. D., Yu J.Y.. Testing simple models of ENSO. J. Atmos. Sci., 2003, 60: 305-318

[49]

Neelin J. D.. The slow sea surface temperature mode and the fast–wave limit: Analytic theory for tropical interannual oscillations and experiments in a hybrid coupled model. J. of the Atmos. Sci., 1991, 48(4): 584-606

[50]

Neelin J. D., Battisti D. S., Hirst A. C. ENSO theory. Journal of Geophysical Research: Oceans, 1998, 103(C7): 14261-14290

[51]

Neelin J. D., Dijkstra H. A.. Ocean–atmosphere interaction and the tropical climatology, Part I: The dangers of flux correction. Journal of climate, 1995, 8(5): 1325-1342

[52]

Neelin J. D., Jin F.F.. Modes of interannual tropical ocean–atmosphere interaction–a unified view, Part II: Analytical results in the weak–coupling limit. Journal of the atmospheric sciences, 1993, 50(21): 3504-3522

[53]

Pazy A.. Semigroups of Linear Operators and Applications to Partial Differential Equations, 1983

[54]

Penland C., Sardeshmukh P. D.. The optimal growth of tropical sea–surface temperature anomalies. J. Climate, 1995, 8(8): 1999-2024

[55]

Philander S. G. H.. El Nieno, La Niena, and the Southern Oscillation, Academic Press, 1992
[56]

Sarachik E. S., Cane M. A.. The El Nieno–Southern Oscillation Phenomenon, 2010

[57]

Temam R.. Sur l’approximation de la solution des équations de Navier–Stokes par la méthode des pas fractionnaires (II). Arch. Ration. Mech. Anal., 1969, 33: 377-385

[58]

Temam R.. Infinite–Dimensional Dynamical Systems in Mechanics and Physics, 1997

[59]

Tziperman E., Cane M. A., Zebiak S. E.. Irregularity and locking to the seasonal cycle in an ENSO prediction model as explained by the quasi–periodicity route to chaos. Journal of the Atmospheric Sciences, 1995, 52(3): 293-306

[60]

Tziperman E., Stone L., Cane M., Jarosh H.. El Nieno chaos: Overlapping of resonances between the seasonal cycle and the Pacific ocean–atmosphere oscillator. Science, 1994, 264(5155): 72-74

[61]

Wang C., Picaut J.. Understanding ENSO physics—A review, in Earth’s Climate: The Ocean–Atmosphere Interaction. Geophys. Monogr., 2004, 147: 21-48
[62]

Wang C., Wang X.. Classifying El Nieno Modoki I and II by different impacts on rainfall in southern China and typhoon tracks. Journal of Climate, 2013, 26(4): 1322-1338

[63]

Yanenko N. N.. The method of fractional steps: the solution of problems of mathematical physics in several variables, 1971

[64]

Zebiak S. E.. A simple atmospheric model of relevance to El Nieno. Journal of the Atmospheric Sciences, 1982, 39(9): 2017-2027

[65]

Zebiak S. E.. Atmospheric convergence feedback in a simple model for El Nieno. Monthly weather review, 1986, 114(7): 1263-1271

[66]

Zebiak S. E., Cane M. A.. A model El Nieno–southern oscillation. Monthly Weather Review, 1987, 115(10): 2262-2278

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