Over the past 15 years, the geometrical and topological methods of the theory of manifolds have assumed a central role in the most advanced areas of pure and applied mathematics as well as theoretical physics. The three volumes of Modern Geometry- Methods and Applications contain a concrete exposition of these methods together with their main application in mathematics and physics. This third volume, presented in highly accessible language, concentrates on homology theory. It contains introduction to the contemporary methods for the calculation of homotopy groups and the classification of manifolds. Both scientists and students of mathematics as well as theoretical physics will find this book to be a valuable reference and text.

Preface
CHAPTER 1
Homology and Cohomology. Computational Recipes
1. Cohomology groups as classes of closed differential forms. Their homotopy invariance
2. The homology theory of algebraic complexes
3. Simplicial complexes. Their homology and cohomology groups. The classification of the two-dimensional closed surfaces
4. Attaching cells to a topological space. Cell spaces. Theorems on the reduction of cell spaces. Homology groups and the fundamental groups of surfaces and certain other manifolds.
5. The singular homology and cohomology groups. Their homotogy invariance. The exact sequence of a pair. Relative homology groups
6. The singular homology of cell complexes. Its equivalence with cell homology. Poincare duality in simplicial homology
7. The homology groups of a product of spaces. Multiplication in cohomology rings. The cohomology theory of H-spaces and Liegroups. The eo homology of the unitary groups
8. The homology theory offibre bundles (skew products)
9. The extension problem for maps, homotopies, and cross-sections. Obstruction cohomology classes
9.1. The extension problem for maps
9.2. The extension problem for homotopies
9.3. The extension problem for cross-sections
10. Homology theory and methods for computing homotopy groups. The Cartan-Serre theorem. Cohomology operations. Vector bundles.
10.1. The concept of a cohomology operation. Examples
10.2. Cohomology operations and Eilenberg-MacLane complexes
10.3. Computation of the rational homotopy groups p_i,?Q
10.4. Application to vector bundles. Characteristic.classes
10.5. Classification of the Steenrod operations in low dimensions
10.6. Computation of the first few non trivial stable homotopy groups of spheres.
10.7. Stable homotopy classes of maps of cell complexes
11. Homology theory and the fundamental group
12. The cohomology groups of hyperelliptic Riemann surfaces. Jacobi tori. Geodesics on multi-axis ellipsoids. Relationship to finite-gapotentials
13. The simplest properties of Kahler manifolds. Abelian tori
14. Sheaf cohomology
CHAPTER 2
Critical Points of Smooth Functions and Homology Theory
15. Morse functions and cell complexes
16. The Morse inequalities
17. Morse-Smale functions. Handles. Surfaces
18. Poincare duality
19. Critical points of smooth functions and the Lyusternik - Shnirelman category of a manifold
20. Critical manifolds and the Morse inequalities. Functions with symmetry
21. Critical points of functionals and the topology of the path space O(M)
22. Applications of the index theorem
23. The periodic problem of the calculus of variations
24. Morse functions on 3-dimensional manifolds and Heegaard splittings
25. Unitary Bott periodicity and higher-dimensional variational problems
25.1. The theorem on unitary periodicity
25.2. Unitary periodicity via the two-dimensional calculus of variations
25.3. Onthogonal periodicity via the higher-dimensional calculus of variations
26. Morse theory and certain motions in the planar nobody problem
CHAPTER 3
Cobordisms and Smooth Structures
27. Characteristic numbers. Cobordisms. Cycles and submanifolds. The signature of a manifold
27.1. Statement of the problem. The simplest facts about cobordisms. The signature
27.2. Thorn complexes. Calculation of cobordisms (modulo torsion). The signature formula. Realization of cycles as submanifolds
27.3. Some applications of the signature formula. The signature and the problem of the invariance of classes
28. Smooth structures on the 7-dimensional sphere. The classification problem for smooth manifolds (normal invariants). Reidemeister torsion and the fundamental hypothesis (Hauptvermutung) of combinatorial topology
Bibliography
APPENDIX 1 (by S. P. Novikov)
An Analogue of Morse Theory for Many-Valued Functions. Certain Properties of Poisson Brackets
APPENDIX 2 (by A. T. Fomenko)
Plateau's Problem. Spectral Bordisms and Globally Minimal Surfaces in Riemannian Manifolds
Index
Errata to Parts I and 11