SPRINGER BRIEFS IN MATHEMATICS Mickaël D. Chekroun Honghu Liu Shouhong Wang Approximation of Stochastic Invariant Manifolds Stochastic Manifolds for Nonlinear SPDEs I SpringerBriefs in Mathematics Series editors Krishnaswami Alladi, Gainesville, USA Nicola Bellomo, Torino, Italy Michele Benzi, Atlanta, USA Tatsien Li, Shanghai, People’s Republic of China Matthias Neufang, Ottawa, Canada Otmar Scherzer, Vienna, Austria Dierk Schleicher, Bremen, Germany Benjamin Steinberg, New York, USA Yuri Tschinkel, New York, USA Loring W. Tu, Medford, USA G. George Yin, Detroit, USA Ping Zhang, Kalamazoo, USA SpringerBriefsinMathematicsshowcasesexpositionsinallareasofmathematics andappliedmathematics.Manuscriptspresentingnewresultsorasinglenewresult inaclassicalfield,newfield,oranemergingtopic,applications,orbridgesbetween newresultsandalreadypublishedworks,areencouraged.Theseriesisintendedfor mathematicians and applied mathematicians. More information about this series at http://www.springer.com/series/10030 ë Micka l D. Chekroun Honghu Liu (cid:129) Shouhong Wang Approximation of Stochastic Invariant Manifolds Stochastic Manifolds for Nonlinear SPDEs I 123 Mickaël D.Chekroun ShouhongWang Universityof California Indiana University Los Angeles, CA Bloomington,IN USA USA Honghu Liu Universityof California Los Angeles, CA USA ISSN 2191-8198 ISSN 2191-8201 (electronic) SpringerBriefs inMathematics ISBN 978-3-319-12495-7 ISBN 978-3-319-12496-4 (eBook) DOI 10.1007/978-3-319-12496-4 LibraryofCongressControlNumber:2014956373 Mathematics Subject Classification: 37L65, 37D10, 37L25, 35B42, 37L10, 37L55, 60H15, 35R60, 34F05,34G20,37L05 SpringerChamHeidelbergNewYorkDordrechtLondon ©TheAuthor(s)2015 Thisworkissubjecttocopyright.AllrightsarereservedbythePublisher,whetherthewholeorpart of the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilms or in any other physical way, and transmission or information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilarmethodologynowknownorhereafterdeveloped. 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Printedonacid-freepaper Springer International Publishing AG Switzerland is part of Springer Science+Business Media (www.springer.com) To our families AnapproximationofastochastichyperbolicmanifoldassociatedwithastochasticBurgers-type equation:x-disintegrationovertheleadingpairofstable/unstablemodes,foragivenrealization . ofthenoise.Thecalculationsarebasedontheformulasderivedinthismonograph;seeChap.7 Preface Theintriguingfigurefromthepreviouspagepresentsavisualizationofthetypeof manifolds this monograph is concerned with. First, obtained as a graph over some chosen linearized spatial modes from a nonlinear stochastic partial differential equation (SPDE), such a manifold—and its geometric properties—depends natu- rally on the spatial variable. Second, the shape of this manifold is nonlinear as a fingerprint of the nonlinear effects conveyed by the nonlinear SPDE. Third, this manifoldisstochastic,inotherwords,itdependsontimeforagivenrealizationof the noise, meaning that “mutations” of the shape—such as changes in the (Gaussian) curvature—can occur as time flows. Manifolds that share these three features and more importantly for which the dynamics of the underlying nonlinear SPDEiseitherattractedtoormeandersaround,arethemanifoldsofinterestinthis two-volume series. In this respect, a pathwise approach from the theory of random dynamical systems (RDS)isadoptedinboth volumes.Volume Ideals with approximation of stochastic manifolds that are invariant for the SPDE dynamics, while Volume II [37] deals with stochastic manifolds that may not be invariant nor attractive and that can still capture essential features of the dynamics through appropriate parameterizations of the small spatial scales by the large ones. The small-scale parameterizations proposed in Volume II are articulated around a new concept of stochastic manifolds, namely the stochastic parameterizing manifolds (PMs). An important common feature is shared by the (pathwise) approximation formulas derived in Volume I and the (pathwise) parameterization techniques introducedinVolumeII:botharecharacterizedaspullbacklimitsfrombackward– forward systems which are only partially coupled, facilitating the calculation of such limits, either analytically or numerically. The aforementioned pullback limits arise under the form of Lyapunov–Perron integrals which are useful for the rigorous treatment of the problem of approxi- mation to the leading order,1 of important stochastic manifolds such as—but not 1 WithrespecttothenonlinearityinvolvedintheSPDEathand. ix x Preface limited to—stochastic critical manifolds2 built as random graphs over a fixed number of critical modes which lose their stability as a control parameter varies. In this respect, Chaps. 6 and 7 contain explicit formulas for the leading-order Taylor approximation of stochastic (local) critical manifolds or more general sto- chastic hyperbolic manifolds. The pullback characterization of these formulas provides a useful interpretation of the corresponding approximating manifolds which gives rise to a simple framework that allows us, furthermore, to unify the previous approximation approaches of stochastic invariant manifolds, as discussed in Volume II; see [37, Sect. 4.1]. To help the reader appreciate this unification as well as the more prospective material presented in Volume II, we took the freedom to include a self-contained (short)surveyonthetheoryofexistenceandattractionofone-parameterfamiliesof stochastic invariant manifolds in Chaps. 4 and 5. Los Angeles, September 2014 Mickaël D. Chekroun Los Angeles Honghu Liu Bloomington Shouhong Wang 2 Includingstochasticmanifoldssuchasthecenterorcenter-unstablemanifolds. Acknowledgments Preliminary versions of this work were presented by the authors at the AIMS SpecialSessionon“AdvancesinClassicalandGeophysicalFluidDynamics,”held at the Ninth AIMS Conference on Dynamical Systems, Differential Equations and Applications in Orlando, July 2012; at the “workshop on Random Dynamical Systems,”heldattheInstituteofMathematicsandApplicationsinOctober2012;at the “Lunch Seminars” held at the Center for Computational and Applied Mathe- matics, Purdue University, in November 2012; at the “Applied Mathematics Seminar,” held at the University of Illinois at Chicago in March 2013; at AMS Special Session on “Partial Differential Equations from Fluid Mechanics,” held at University of Louisville in October 2013; at the “PDE seminar,” held at Indiana University in October 2013; and at the Alpine Summer School on Dynamics, Stochastics, and Predictability of the Climate System, Valle d’Aosta, Italy in June 2014. We would like to thank all those who helped in the realization of this book through encouragement, advice, or scientific exchanges: Jerry Bona, Jerome Darbon,JinqiaoDuan,MichaelGhil,NathanGlatt-Holtz,DmitriKondrashov,Tian Ma,JamesMcWilliams,DavidNeelin,JamesRobinson,JeanRoux,EricSimonnet, Roger Temam, Yohann Tendero, and Kevin Zumbrun. More particularly, the authors are grateful to Michael Ghil for his constant support and interest in this work, overthe years. MDC isgrateful toJames McWilliams andDavid Neelin for stimulating discussions on the closure problem of turbulence and stochastic parameterizations; and to Michael Ghil and Roger Temam for stimulating discus- sionsontheslowandthe“fuzzy”manifold.MDCthanksalsoJinqiaoDuanforthe reference [103], and for discussions on stochastic invariant manifolds. We would like to express also our thanks to Ute McCrory (Springer) for her invaluable patience and support during the preparation of this book. MDC and HL are supported by the National Science Foundation grant DMS- 1049253 and Office of Naval Research grant N00014-12-1-0911. SW is supported in part by National Science Foundation grants DMS-1211218 and DMS-1049114, and by Office of Naval Research grant N00014-11-1-0404. SW is most grateful to xi