On the Conical Novikov Homology

Abstract

Let ω be a Morse form on a manifold M. Let p: M M be a regular covering with structure group G, such that p*([ω])=0. Let :GR be the corresponding period homomorphism. Denote by the Novikov completion of the group ring Z G. Choose a transverse ω-gradient v. Counting the flow lines of v one defines the Novikov complex N* freely generated over by the set of zeroes of ω. In this paper we introduce a refinement of this construction. We define a subring of and show that the Novikov complex N* is defined actually over and computes the homology of the chain complex C*( M) . When G≈Z2, and the irrationality degree of equals 2, the ring is isomorphic to the ring of series in 2 variables x, y of the form Σr∈N ar xnrymr where ar, nr, mr∈Z and both nr, \ mr converge to ∞ when r ∞. The algebraic part of the proof is based on a suitable generalization of the classical algorithm of approximating irrational numbers by rationals. The geometric part is a straightforward generalization of the author's proof of the particular case of this theorem concerning the circle-valued Morse maps. In Appendix 1 we give an overview of E. Pitcher's work on circle-valued Morse theory (1939). We show that Pitcher's lower bounds for the number of critical points of a circle-valued Morse map coincide with the torsion-free part of the Novikov inequalities. In Appendix 2 we construct a circle-valued Morse map and its gradient such that its unique Novikov incidence coefficient is a power series in one variable with an arbitrarily small convergence radius.