Complex bordism
Taras Panov (Talk | contribs) (→Adams-Novikov spectral sequence) |
Taras Panov (Talk | contribs) |
||
Line 127: | Line 127: | ||
[[Category:Manifolds]] | [[Category:Manifolds]] | ||
+ | [[Category:Bordism]] | ||
{{Stub}} | {{Stub}} |
Revision as of 20:27, 10 March 2010
An earlier version of this page was published in the Bulletin of the Manifold Atlas: screen, print. You may view the version used for publication as of 09:39, 1 April 2011 and the changes since publication. |
The user responsible for this page is Taras Panov. No other user may edit this page at present. |
Contents |
1 Introduction
Complex bordisms (also known as unitary bordisms) is the bordism theory of stably complex manifolds. It is one of the most important theory of bordisms with additional structure, or B-bordisms.
The theory of complex bordisms is much richer than its unoriented analogue, and at the same time is not as complicated as oriented bordisms or other bordisms with additional structure (B-bordisms). Thanks to this, the complex cobordism theory found the most stricking and important applications in algebraic topology and beyond. Many of these applications, including the formal group techniques and Adams-Novikov spectral sequence were outlined in the pioneering work [Novikov1967].
2 Stably complex structures
A direct attempt to define the bordism relation on complex manifolds fails because the manifold is odd-dimensional and therefore cannot be complex. In order to work with complex manifolds in the bordism theory, one needs to weaken the notion of the complex structures. This leads directly to considering stably complex (also known as weakly almost complex, stably almost complex or quasicomplex) manifolds.
Let denote the tangent bundle of , and the product vector bundle over . A tangential stably complex structure on is determined by a choice of an isomorphism
between the "stable" tangent bundle and a complex vector bundle over . Some of the choices of such isomorphisms are deemed to be equivalent, i.e. determining the same stably complex structures (see details in Chapters II and VII of [Stong1968]). In particular, two stably complex structures are equivalent if they differ by a trivial complex summand. A normal stably complex structure on is determined by a choice of a complex bundle structure in the normal bundle of an embedding . A tangential and normal stably complex structures on determine each other by means of the canonical isomorphism . We therefore may restrict our attention to tangential structures only.
A stably complex manifold is a pair consisting of a manifold and a stably complex structure on it. This is a generalisation to a complex and almost complex manifold (where the latter means a manifold with a choice of a complex structure on , i.e. a stably complex structure with ).
Example 2.1. Let . The standard complex structure on is equivalent to a stably complex structure determined by the isomorphism
where is the Hopf line bundle. On the other hand, the isomorphism
determines a trivial stably complex structure on .
3 Definition of bordism and cobordism
The bordism relation can be defined between stably complex manifolds. Like the case of unoriented bordisms, the set of bordism classes of stably complex manifolds is an Abelian group with respect to the disjoint union. This group is called the group of -dimensional complex bordisms and denoted . A zero is represented by the bordism class of any manifold which bounds and whose stable tangent bundle is trivial (and therefore isomorphic to a product complex vector bundle ). The sphere provides an example of such a manifold. The opposite element to the bordism class in the group may be represented by the same manifold with the stably complex structure determined by the isomorphism
where is given by .
An abbreviated notation for the complex bordism class will be used whenever the stably complex structure is clear from the context.
The groups of complex bordisms and cobordisms of a space are defined similarly to the unoriented case:
where is the Thom space of the universal complex -plane bundle . These groups are -modules and give rise to a multiplicative (co)homology theory. In particular, is a graded ring.
The graded ring with is called the complex cobordism ring; it has nontrivial elements only in nonpositively graded components.
4 Geometric cobordisms
5 Structure results
6 Multiplicative generators
7 Formal group laws and genera
8 Adams-Novikov spectral sequence
The main references here are [Novikov1967] and [Ravenel1986]
9 References
- [Novikov1967] S. P. Novikov, Methods of algebraic topology from the point of view of cobordism theory, Math. USSR, Izv. 1, (1967) 827–913. MR0221509 (36 #4561) Zbl 0176.52401
- [Ravenel1986] D. C. Ravenel, Complex cobordism and stable homotopy groups of spheres, Academic Press Inc., Orlando, FL, 1986. MR860042 (87j:55003) Zbl 1073.55001
- [Stong1968] R. E. Stong, Notes on cobordism theory, Princeton University Press, Princeton, N.J., 1968. MR0248858 (40 #2108) Zbl 0277.57010
This page has not been refereed. The information given here might be incomplete or provisional. |