Stratifold
In differential topology, a branch of mathematics, a stratifold is a generalization of a differentiable manifold where certain kinds of singularities are allowed. More specifically a stratifold is stratified into differentiable manifolds of (possibly) different dimensions. Stratifolds can be used to construct new homology theories. For example, they provide a new geometric model for ordinary homology. The concept of stratifolds was invented by Matthias Kreck. The basic idea is similar to that of a topologically stratified space, but adapted to differential topology.
Definitions
Before we come to stratifolds, we define a preliminary notion, which captures the minimal notion for a smooth structure on a space: A differential space (in the sense of Sikorski) is a pair [math]\displaystyle{ (X, C), }[/math] where X is a topological space and C is a subalgebra of the continuous functions [math]\displaystyle{ X \to \R }[/math] such that a function is in C if it is locally in C and [math]\displaystyle{ g \circ \left(f_1, \ldots, f_n\right) : X \to \R }[/math] is in C for [math]\displaystyle{ g : \R^n \to \R }[/math] smooth and [math]\displaystyle{ f_i \in C. }[/math] A simple example takes for X a smooth manifold and for C just the smooth functions.
For a general differential space [math]\displaystyle{ (X, C) }[/math] and a point x in X we can define as in the case of manifolds a tangent space [math]\displaystyle{ T_x X }[/math] as the vector space of all derivations of function germs at x. Define strata [math]\displaystyle{ X_i = \{x\in X : T_x X }[/math] has dimension i[math]\displaystyle{ \}. }[/math] For an n-dimensional manifold M we have that [math]\displaystyle{ M_n = M }[/math] and all other strata are empty. We are now ready for the definition of a stratifold, where more than one stratum may be non-empty:
A k-dimensional stratifold is a differential space [math]\displaystyle{ (S, C), }[/math] where S is a locally compact Hausdorff space with countable base of topology. All skeleta should be closed. In addition we assume:
- The [math]\displaystyle{ \left(S_i, C|_{S_i}\right) }[/math] are i-dimensional smooth manifolds.
- For all x in S, restriction defines an isomorphism of stalks [math]\displaystyle{ C_x \to C^{\infty}(S_i)_x. }[/math]
- All tangent spaces have dimension ≤ k.
- For each x in S and every neighbourhood U of x, there exists a function [math]\displaystyle{ \rho : U \to \R }[/math] with [math]\displaystyle{ \rho(x) \neq 0 }[/math] and [math]\displaystyle{ \text{supp}(\rho) \subset U }[/math] (a bump function).
A n-dimensional stratifold is called oriented if its (n − 1)-stratum is empty and its top stratum is oriented. One can also define stratifolds with boundary, the so-called c-stratifolds. One defines them as a pair [math]\displaystyle{ (T,\partial T) }[/math] of topological spaces such that [math]\displaystyle{ T-\partial T }[/math] is an n-dimensional stratifold and [math]\displaystyle{ \partial T }[/math] is an (n − 1)-dimensional stratifold, together with an equivalence class of collars.
An important subclass of stratifolds are the regular stratifolds, which can be roughly characterized as looking locally around a point in the i-stratum like the i-stratum times a (n − i)-dimensional stratifold. This is a condition which is fulfilled in most stratifold one usually encounters.
Examples
There are plenty of examples of stratifolds. The first example to consider is the open cone over a manifold M. We define a continuous function from S to the reals to be in C if and only if it is smooth on [math]\displaystyle{ M \times (0, 1) }[/math] and it is locally constant around the cone point. The last condition is automatic by point 2 in the definition of a stratifold. We can substitute M by a stratifold S in this construction. The cone is oriented if and only if S is oriented and not zero-dimensional. If we consider the (closed) cone with bottom, we get a stratifold with boundary S.
Other examples for stratifolds are one-point compactifications and suspensions of manifolds, (real) algebraic varieties with only isolated singularities and (finite) simplicial complexes.
Bordism theories
In this section, we will assume all stratifolds to be regular. We call two maps [math]\displaystyle{ S, S' \to X }[/math] from two oriented compact k-dimensional stratifolds into a space X bordant if there exists an oriented (k + 1)-dimensional compact stratifold T with boundary S + (−S') such that the map to X extends to T. The set of equivalence classes of such maps [math]\displaystyle{ S \to X }[/math] is denoted by [math]\displaystyle{ SH_k X. }[/math] The sets have actually the structure of abelian groups with disjoint union as addition. One can develop enough differential topology of stratifolds to show that these define a homology theory. Clearly, [math]\displaystyle{ SH_k(\text{point}) = 0 }[/math] for [math]\displaystyle{ k \gt 0 }[/math] since every oriented stratifold S is the boundary of its cone, which is oriented if [math]\displaystyle{ \dim(S) \gt 0. }[/math] One can show that [math]\displaystyle{ SH_0(\text{point})\cong\Z. }[/math] Hence, by the Eilenberg–Steenrod uniqueness theorem, [math]\displaystyle{ SH_k(X) \cong H_k(X) }[/math] for every space X homotopy-equivalent to a CW-complex, where H denotes singular homology. For other spaces these two homology theories need not be isomorphic (an example is the one-point compactification of the surface of infinite genus).
There is also a simple way to define equivariant homology with the help of stratifolds. Let G be a compact Lie group. We can then define a bordism theory of stratifolds mapping into a space X with a G-action just as above, only that we require all stratifolds to be equipped with an orientation-preserving free G-action and all maps to be G-equivariant. Denote by [math]\displaystyle{ SH_k^G(X) }[/math] the bordism classes. One can prove [math]\displaystyle{ SH_k^G(X)\cong H_{k-\dim(G)}^G(X) }[/math] for every X homotopy equivalent to a CW-complex.
Connection to the theory of genera
A genus is a ring homomorphism from a bordism ring into another ring. For example, the Euler characteristic defines a ring homomorphism [math]\displaystyle{ \Omega^O(\text{point}) \to \Z/2[t] }[/math] from the unoriented bordism ring and the signature defines a ring homomorphism [math]\displaystyle{ \Omega^{SO}(\text{point}) \to \Z[t] }[/math] from the oriented bordism ring. Here t has in the first case degree 1 and in the second case degree 4, since only manifolds in dimensions divisible by 4 can have non-zero signature. The left hand sides of these homomorphisms are homology theories evaluated at a point. With the help of stratifolds it is possible to construct homology theories such that the right hand sides are these homology theories evaluated at a point, the Euler homology and the Hirzebruch homology respectively.
Umkehr maps
Suppose, one has a closed embedding [math]\displaystyle{ i : N\hookrightarrow M }[/math] of manifolds with oriented normal bundle. Then one can define an umkehr map [math]\displaystyle{ H_k(M) \to H_{k+\dim(N)-\dim(M)}(N). }[/math] One possibility is to use stratifolds: represent a class [math]\displaystyle{ x \in H_k(M) }[/math] by a stratifold [math]\displaystyle{ f : S \to M. }[/math] Then make ƒ transversal to N. The intersection of S and N defines a new stratifold S' with a map to N, which represents a class in [math]\displaystyle{ H_{k+\dim(N)-\dim(M)}(N). }[/math] It is possible to repeat this construction in the context of an embedding of Hilbert manifolds of finite codimension, which can be used in string topology.
References
- M. Kreck, Differential Algebraic Topology: From Stratifolds to Exotic Spheres, AMS (2010), ISBN:0-8218-4898-4
- The stratifold page
- Euler homology
Original source: https://en.wikipedia.org/wiki/Stratifold.
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