04057nam 2200697Ia 450 991082591060332120200520144314.01-282-19426-797866121942693-11-019797-910.1515/9783110197976(CKB)1000000000688550(EBL)314061(OCoLC)236337992(SSID)ssj0000122343(PQKBManifestationID)11142716(PQKBTitleCode)TC0000122343(PQKBWorkID)10123464(PQKB)10766657(MiAaPQ)EBC314061(DE-B1597)32310(OCoLC)979969284(DE-B1597)9783110197976(Au-PeEL)EBL314061(CaPaEBR)ebr10194856(CaONFJC)MIL219426(OCoLC)935264247(PPN)17549326X(EXLCZ)99100000000068855020070105d2006 uy 0engurcn|||||||||txtrdacontentcrdamediacrrdacarrierCircle-valued Morse theory[electronic resource] /Andrei V. PajitnovBerlin ;New York De Gruyterc20061 online resource (464 pages)De Gruyter studies in mathematics,0179-0986 ;32Description based upon print version of record.3-11-015807-8 Includes bibliographical references (p. [437]-444) and index.Front matter --Contents --Preface --Introduction --Part 1. Morse functions and vector fields on manifolds --CHAPTER 1. Vector fields and C0 topology --CHAPTER 2. Morse functions and their gradients --CHAPTER 3. Gradient flows of real-valued Morse functions --Part 2. Transversality, handles, Morse complexes --CHAPTER 4. The Kupka-Smale transversality theory for gradient flows --CHAPTER 5. Handles --CHAPTER 6. The Morse complex of a Morse function --Part 3. Cellular gradients --CHAPTER 7. Condition (C) --CHAPTER 8. Cellular gradients are C0-generic --CHAPTER 9. Properties of cellular gradients --Part 4. Circle-valued Morse maps and Novikov complexes --CHAPTER 10. Completions of rings, modules and complexes --CHAPTER 11. The Novikov complex of a circle-valued Morse map --CHAPTER 12. Cellular gradients of circle-valued Morse functions and the Rationality Theorem --CHAPTER 13. Counting closed orbits of the gradient flow --CHAPTER 14. Selected topics in the Morse-Novikov theory --BackmatterIn the early 1920's M. Morse discovered that the number of critical points of a smooth function on a manifold is closely related to the topology of the manifold. This became a starting point of the Morse theory which is now one of the basic parts of differential topology. Circle-valued Morse theory originated from a problem in hydrodynamics studied by S. P. Novikov in the early 1980's. Nowadays, it is a constantly growing field of contemporary mathematics with applications and connections to many geometrical problems such as Arnold's conjecture in the theory of Lagrangian intersections, fibrations of manifolds over the circle, dynamical zeta functions, and the theory of knots and links in the three-dimensional sphere. The aim of the book is to give a systematic treatment of geometric foundations of the subject and recent research results. The book is accessible to first year graduate students specializing in geometry and topology.Gruyter studies in mathematics ;32.Morse theoryManifolds (Mathematics)Differential geometry.Morse theory.Morse theory.Manifolds (Mathematics)514/.74SK 350rvkPajitnov Andrei V1671300MiAaPQMiAaPQMiAaPQBOOK9910825910603321Circle-valued Morse theory4033770UNINA