Stiefel–Whitney class (original) (raw)

Set of topological invariants

In mathematics, in particular in algebraic topology and differential geometry, the Stiefel–Whitney classes are a set of topological invariants of a real vector bundle that describe the obstructions to constructing everywhere independent sets of sections of the vector bundle. Stiefel–Whitney classes are indexed from 0 to n, where n is the rank of the vector bundle. If the Stiefel–Whitney class of index i is nonzero, then there cannot exist ( n − i + 1 ) {\displaystyle (n-i+1)} $(n-i+1)$ everywhere linearly independent sections of the vector bundle. A nonzero _n_th Stiefel–Whitney class indicates that every section of the bundle must vanish at some point. A nonzero first Stiefel–Whitney class indicates that the vector bundle is not orientable. For example, the first Stiefel–Whitney class of the Möbius strip, as a line bundle over the circle, is not zero, whereas the first Stiefel–Whitney class of the trivial line bundle over the circle, S 1 × R {\displaystyle S^{1}\times \mathbb {R} } $S^{1}\times \mathbb {R}$ , is zero.

The Stiefel–Whitney class was named for Eduard Stiefel and Hassler Whitney and is an example of a Z / 2 Z {\displaystyle \mathbb {Z} /2\mathbb {Z} } $\mathbb {Z} /2\mathbb {Z}$ -characteristic class associated to real vector bundles.

In algebraic geometry one can also define analogous Stiefel–Whitney classes for vector bundles with a non-degenerate quadratic form, taking values in etale cohomology groups or in Milnor K-theory. As a special case one can define Stiefel–Whitney classes for quadratic forms over fields, the first two cases being the discriminant and the Hasse–Witt invariant (Milnor 1970).

General presentation

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For a real vector bundle E, the Stiefel–Whitney class of E is denoted by w(E). It is an element of the cohomology ring

H ∗ ( X ; Z / 2 Z ) = ⨁ i ≥ 0 H i ( X ; Z / 2 Z ) {\displaystyle H^{\ast }(X;\mathbb {Z} /2\mathbb {Z} )=\bigoplus _{i\geq 0}H^{i}(X;\mathbb {Z} /2\mathbb {Z} )} $H^{\ast }(X;\mathbb {Z} /2\mathbb {Z} )=\bigoplus _{i\geq 0}H^{i}(X;\mathbb {Z} /2\mathbb {Z} )$

where X is the base space of the bundle E, and Z / 2 Z {\displaystyle \mathbb {Z} /2\mathbb {Z} } $\mathbb {Z} /2\mathbb {Z}$ (often alternatively denoted by Z 2 {\displaystyle \mathbb {Z} _{2}} $\mathbb {Z} _{2}$ ) is the commutative ring whose only elements are 0 and 1. The component of w ( E ) {\displaystyle w(E)} $w(E)$ in H i ( X ; Z / 2 Z ) {\displaystyle H^{i}(X;\mathbb {Z} /2\mathbb {Z} )} $H^{i}(X;\mathbb {Z} /2\mathbb {Z} )$ is denoted by w i ( E ) {\displaystyle w_{i}(E)} $w_{i}(E)$ and called the _i_-th Stiefel–Whitney class of E. Thus,

w ( E ) = w 0 ( E ) + w 1 ( E ) + w 2 ( E ) + ⋯ {\displaystyle w(E)=w_{0}(E)+w_{1}(E)+w_{2}(E)+\cdots } $w(E)=w_{0}(E)+w_{1}(E)+w_{2}(E)+\cdots$ ,

where each w i ( E ) {\displaystyle w_{i}(E)} $w_{i}(E)$ is an element of H i ( X ; Z / 2 Z ) {\displaystyle H^{i}(X;\mathbb {Z} /2\mathbb {Z} )} $H^{i}(X;\mathbb {Z} /2\mathbb {Z} )$ .

The Stiefel–Whitney class w ( E ) {\displaystyle w(E)} $w(E)$ is an invariant of the real vector bundle E; i.e., when F is another real vector bundle which has the same base space X as E, and if F is isomorphic to E, then the Stiefel–Whitney classes w ( E ) {\displaystyle w(E)} $w(E)$ and w ( F ) {\displaystyle w(F)} $w(F)$ are equal. (Here isomorphic means that there exists a vector bundle isomorphism E → F {\displaystyle E\to F} $E\to F$ which covers the identity i d X : X → X {\displaystyle \mathrm {id} _{X}\colon X\to X} $\mathrm {id} _{X}\colon X\to X$ .) While it is in general difficult to decide whether two real vector bundles E and F are isomorphic, the Stiefel–Whitney classes w ( E ) {\displaystyle w(E)} $w(E)$ and w ( F ) {\displaystyle w(F)} $w(F)$ can often be computed easily. If they are different, one knows that E and F are not isomorphic.

As an example, over the circle S 1 {\displaystyle S^{1}} $S^{1}$ , there is a line bundle (i.e., a real vector bundle of rank 1) that is not isomorphic to a trivial bundle. This line bundle L is the Möbius strip (which is a fiber bundle whose fibers can be equipped with vector space structures in such a way that it becomes a vector bundle). The cohomology group H 1 ( S 1 ; Z / 2 Z ) {\displaystyle H^{1}(S^{1};\mathbb {Z} /2\mathbb {Z} )} $H^{1}(S^{1};\mathbb {Z} /2\mathbb {Z} )$ has just one element other than 0. This element is the first Stiefel–Whitney class w 1 ( L ) {\displaystyle w_{1}(L)} $w_{1}(L)$ of L. Since the trivial line bundle over S 1 {\displaystyle S^{1}} $S^{1}$ has first Stiefel–Whitney class 0, it is not isomorphic to L.

Two real vector bundles E and F which have the same Stiefel–Whitney class are not necessarily isomorphic. This happens for instance when E and F are trivial real vector bundles of different ranks over the same base space X. It can also happen when E and F have the same rank: the tangent bundle of the 2-sphere S 2 {\displaystyle S^{2}} $S^{2}$ and the trivial real vector bundle of rank 2 over S 2 {\displaystyle S^{2}} $S^{2}$ have the same Stiefel–Whitney class, but they are not isomorphic. But if two real line bundles over X have the same Stiefel–Whitney class, then they are isomorphic.

The Stiefel–Whitney classes w i ( E ) {\displaystyle w_{i}(E)} $w_{i}(E)$ get their name because Eduard Stiefel and Hassler Whitney discovered them as mod-2 reductions of the obstruction classes to constructing n − i + 1 {\displaystyle n-i+1} $n-i+1$ everywhere linearly independent sections of the vector bundle E restricted to the _i_-skeleton of X. Here n denotes the dimension of the fibre of the vector bundle F → E → X {\displaystyle F\to E\to X} $F\to E\to X$ .

To be precise, provided X is a CW-complex, Whitney defined classes W i ( E ) {\displaystyle W_{i}(E)} $W_{i}(E)$ in the _i_-th cellular cohomology group of X with twisted coefficients. The coefficient system being the ( i − 1 ) {\displaystyle (i-1)} $(i-1)$ -st homotopy group of the Stiefel manifold V n − i + 1 ( F ) {\displaystyle V_{n-i+1}(F)} $V_{n-i+1}(F)$ of n − i + 1 {\displaystyle n-i+1} $n-i+1$ linearly independent vectors in the fibres of E. Whitney proved that W i ( E ) = 0 {\displaystyle W_{i}(E)=0} $W_{i}(E)=0$ if and only if E, when restricted to the _i_-skeleton of X, has n − i + 1 {\displaystyle n-i+1} $n-i+1$ linearly-independent sections.

Since π i − 1 V n − i + 1 ( F ) {\displaystyle \pi _{i-1}V_{n-i+1}(F)} $\pi _{i-1}V_{n-i+1}(F)$ is either infinite-cyclic or isomorphic to Z / 2 Z {\displaystyle \mathbb {Z} /2\mathbb {Z} } $\mathbb {Z} /2\mathbb {Z}$ , there is a canonical reduction of the W i ( E ) {\displaystyle W_{i}(E)} $W_{i}(E)$ classes to classes w i ( E ) ∈ H i ( X ; Z / 2 Z ) {\displaystyle w_{i}(E)\in H^{i}(X;\mathbb {Z} /2\mathbb {Z} )} $w_{i}(E)\in H^{i}(X;\mathbb {Z} /2\mathbb {Z} )$ which are the Stiefel–Whitney classes. Moreover, whenever π i − 1 V n − i + 1 ( F ) = Z / 2 Z {\displaystyle \pi _{i-1}V_{n-i+1}(F)=\mathbb {Z} /2\mathbb {Z} } $\pi _{i-1}V_{n-i+1}(F)=\mathbb {Z} /2\mathbb {Z}$ , the two classes are identical. Thus, w 1 ( E ) = 0 {\displaystyle w_{1}(E)=0} $w_{1}(E)=0$ if and only if the bundle E → X {\displaystyle E\to X} $E\to X$ is orientable.

The w 0 ( E ) {\displaystyle w_{0}(E)} $w_{0}(E)$ class contains no information, because it is equal to 1 by definition. Its creation by Whitney was an act of creative notation, allowing the Whitney sum Formula w ( E 1 ⊕ E 2 ) = w ( E 1 ) w ( E 2 ) {\displaystyle w(E_{1}\oplus E_{2})=w(E_{1})w(E_{2})} $w(E_{1}\oplus E_{2})=w(E_{1})w(E_{2})$ to be true.

Throughout, H i ( X ; G ) {\displaystyle H^{i}(X;G)} $H^{i}(X;G)$ denotes singular cohomology of a space X with coefficients in the group G. The word map means always a continuous function between topological spaces.

Axiomatic definition

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The Stiefel-Whitney characteristic class w ( E ) ∈ H ∗ ( X ; Z / 2 Z ) {\displaystyle w(E)\in H^{*}(X;\mathbb {Z} /2\mathbb {Z} )} $w(E)\in H^{*}(X;\mathbb {Z} /2\mathbb {Z} )$ of a finite rank real vector bundle E on a paracompact base space X is defined as the unique class such that the following axioms are fulfilled:

Normalization: The Whitney class of the tautological line bundle over the real projective space P 1 ( R ) {\displaystyle \mathbf {P} ^{1}(\mathbb {R} )} $\mathbf {P} ^{1}(\mathbb {R} )$ is nontrivial, i.e., w ( γ 1 1 ) = 1 + a ∈ H ∗ ( P 1 ( R ) ; Z / 2 Z ) = ( Z / 2 Z ) [ a ] / ( a 2 ) {\displaystyle w(\gamma _{1}^{1})=1+a\in H^{*}(\mathbf {P} ^{1}(\mathbb {R} );\mathbb {Z} /2\mathbb {Z} )=(\mathbb {Z} /2\mathbb {Z} )[a]/(a^{2})} $w(\gamma _{1}^{1})=1+a\in H^{*}(\mathbf {P} ^{1}(\mathbb {R} );\mathbb {Z} /2\mathbb {Z} )=(\mathbb {Z} /2\mathbb {Z} )[a]/(a^{2})$ .
Rank: w 0 ( E ) = 1 ∈ H 0 ( X ) , {\displaystyle w_{0}(E)=1\in H^{0}(X),} $w_{0}(E)=1\in H^{0}(X),$ and for i above the rank of E, w i = 0 ∈ H i ( X ) {\displaystyle w_{i}=0\in H^{i}(X)} $w_{i}=0\in H^{i}(X)$ , that is, w ( E ) ∈ H ⩽ r a n k ( E ) ( X ) . {\displaystyle w(E)\in H^{\leqslant \mathrm {rank} (E)}(X).} $w(E)\in H^{\leqslant \mathrm {rank} (E)}(X).$
Whitney product formula: w ( E ⊕ F ) = w ( E ) ⌣ w ( F ) {\displaystyle w(E\oplus F)=w(E)\smile w(F)} $w(E\oplus F)=w(E)\smile w(F)$ , that is, the Whitney class of a direct sum is the cup product of the summands' classes.
Naturality: w ( f ∗ E ) = f ∗ w ( E ) {\displaystyle w(f^{*}E)=f^{*}w(E)} $w(f^{*}E)=f^{*}w(E)$ for any real vector bundle E → X {\displaystyle E\to X} $E\to X$ and map f : X ′ → X {\displaystyle f\colon X'\to X} $f\colon X'\to X$ , where f ∗ E {\displaystyle f^{*}E} $f^{*}E$ denotes the pullback vector bundle.

The uniqueness of these classes is proved for example, in section 17.2 – 17.6 in Husemoller or section 8 in Milnor and Stasheff. There are several proofs of the existence, coming from various constructions, with several different flavours, their coherence is ensured by the unicity statement.

Definition via infinite Grassmannians

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The infinite Grassmannians and vector bundles

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This section describes a construction using the notion of classifying space.

For any vector space V, let G r n ( V ) {\displaystyle Gr_{n}(V)} $Gr_{n}(V)$ denote the Grassmannian, the space of _n_-dimensional linear subspaces of V, and denote the infinite Grassmannian

G r n = G r n ( R ∞ ) {\displaystyle Gr_{n}=Gr_{n}(\mathbb {R} ^{\infty })} $Gr_{n}=Gr_{n}(\mathbb {R} ^{\infty })$ .

Recall that it is equipped with the tautological bundle γ n → G r n , {\displaystyle \gamma ^{n}\to Gr_{n},} $\gamma ^{n}\to Gr_{n},$ a rank n vector bundle that can be defined as the subbundle of the trivial bundle of fiber V whose fiber at a point W ∈ G r n ( V ) {\displaystyle W\in Gr_{n}(V)} $W\in Gr_{n}(V)$ is the subspace represented by W.

Let f : X → G r n {\displaystyle f\colon X\to Gr_{n}} $f\colon X\to Gr_{n}$ , be a continuous map to the infinite Grassmannian. Then, up to isomorphism, the bundle induced by the map f on X

f ∗ γ n ∈ V e c t n ( X ) {\displaystyle f^{*}\gamma ^{n}\in \mathrm {Vect} _{n}(X)} $f^{*}\gamma ^{n}\in \mathrm {Vect} _{n}(X)$

depends only on the homotopy class of the map [_f_]. The pullback operation thus gives a morphism from the set

[ X ; G r n ] {\displaystyle [X;Gr_{n}]} $[X;Gr_{n}]$

of maps X → G r n {\displaystyle X\to Gr_{n}} $X\to Gr_{n}$ modulo homotopy equivalence, to the set

V e c t n ( X ) {\displaystyle \mathrm {Vect} _{n}(X)} $\mathrm {Vect} _{n}(X)$

of isomorphism classes of vector bundles of rank n over X.

(The important fact in this construction is that if X is a paracompact space, this map is a bijection. This is the reason why we call infinite Grassmannians the classifying spaces of vector bundles.)

Now, by the naturality axiom (4) above, w j ( f ∗ γ n ) = f ∗ w j ( γ n ) {\displaystyle w_{j}(f^{*}\gamma ^{n})=f^{*}w_{j}(\gamma ^{n})} $w_{j}(f^{*}\gamma ^{n})=f^{*}w_{j}(\gamma ^{n})$ . So it suffices in principle to know the values of w j ( γ n ) {\displaystyle w_{j}(\gamma ^{n})} $w_{j}(\gamma ^{n})$ for all j. However, the cohomology ring H ∗ ( G r n , Z 2 ) {\displaystyle H^{*}(Gr_{n},\mathbb {Z} _{2})} $H^{*}(Gr_{n},\mathbb {Z} _{2})$ is free on specific generators x j ∈ H j ( G r n , Z 2 ) {\displaystyle x_{j}\in H^{j}(Gr_{n},\mathbb {Z} _{2})} $x_{j}\in H^{j}(Gr_{n},\mathbb {Z} _{2})$ arising from a standard cell decomposition, and it then turns out that these generators are in fact just given by x j = w j ( γ n ) {\displaystyle x_{j}=w_{j}(\gamma ^{n})} $x_{j}=w_{j}(\gamma ^{n})$ . Thus, for any rank-n bundle, w j = f ∗ x j {\displaystyle w_{j}=f^{*}x_{j}} $w_{j}=f^{*}x_{j}$ , where f is the appropriate classifying map. This in particular provides one proof of the existence of the Stiefel–Whitney classes.

The case of line bundles

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We now restrict the above construction to line bundles, ie we consider the space, V e c t 1 ( X ) {\displaystyle \mathrm {Vect} _{1}(X)} $\mathrm {Vect} _{1}(X)$ of line bundles over X. The Grassmannian of lines G r 1 {\displaystyle Gr_{1}} $Gr_{1}$ is just the infinite projective space

P ∞ ( R ) = R ∞ / R ∗ , {\displaystyle \mathbf {P} ^{\infty }(\mathbf {R} )=\mathbf {R} ^{\infty }/\mathbf {R} ^{*},} $\mathbf {P} ^{\infty }(\mathbf {R} )=\mathbf {R} ^{\infty }/\mathbf {R} ^{*},$

which is doubly covered by the infinite sphere S ∞ {\displaystyle S^{\infty }} $S^{\infty }$ with antipodal points as fibres. This sphere S ∞ {\displaystyle S^{\infty }} $S^{\infty }$ is contractible, so we have

π 1 ( P ∞ ( R ) ) = Z / 2 Z π i ( P ∞ ( R ) ) = π i ( S ∞ ) = 0 i > 1 {\displaystyle {\begin{aligned}\pi _{1}(\mathbf {P} ^{\infty }(\mathbf {R} ))&=\mathbf {Z} /2\mathbf {Z} \\\pi _{i}(\mathbf {P} ^{\infty }(\mathbf {R} ))&=\pi _{i}(S^{\infty })=0&&i>1\end{aligned}}} ${\begin{aligned}\pi _{1}(\mathbf {P} ^{\infty }(\mathbf {R} ))&=\mathbf {Z} /2\mathbf {Z} \\\pi _{i}(\mathbf {P} ^{\infty }(\mathbf {R} ))&=\pi _{i}(S^{\infty })=0&&i>1\end{aligned}}$

Hence P∞(R) is the Eilenberg-Maclane space K ( Z / 2 Z , 1 ) {\displaystyle K(\mathbb {Z} /2\mathbb {Z} ,1)} $K(\mathbb {Z} /2\mathbb {Z} ,1)$ .

It is a property of Eilenberg-Maclane spaces, that

[ X ; P ∞ ( R ) ] = H 1 ( X ; Z / 2 Z ) {\displaystyle \left[X;\mathbf {P} ^{\infty }(\mathbf {R} )\right]=H^{1}(X;\mathbb {Z} /2\mathbb {Z} )} $\left[X;\mathbf {P} ^{\infty }(\mathbf {R} )\right]=H^{1}(X;\mathbb {Z} /2\mathbb {Z} )$

for any X, with the isomorphism given by f → _f*_η, where η is the generator

H 1 ( P ∞ ( R ) ; Z / 2 Z ) = Z / 2 Z {\displaystyle H^{1}(\mathbf {P} ^{\infty }(\mathbf {R} );\mathbf {Z} /2\mathbf {Z} )=\mathbb {Z} /2\mathbb {Z} } $H^{1}(\mathbf {P} ^{\infty }(\mathbf {R} );\mathbf {Z} /2\mathbf {Z} )=\mathbb {Z} /2\mathbb {Z}$ .

Applying the former remark that α : [X, _Gr_1] → Vect1(X) is also a bijection, we obtain a bijection

w 1 : Vect 1 ( X ) → H 1 ( X ; Z / 2 Z ) {\displaystyle w_{1}\colon {\text{Vect}}_{1}(X)\to H^{1}(X;\mathbf {Z} /2\mathbf {Z} )} $w_{1}\colon {\text{Vect}}_{1}(X)\to H^{1}(X;\mathbf {Z} /2\mathbf {Z} )$

this defines the Stiefel–Whitney class _w_1 for line bundles.

The group of line bundles

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If Vect1(X) is considered as a group under the operation of tensor product, then the Stiefel–Whitney class, _w_1 : Vect1(X) → _H_1(X; Z/2Z), is an isomorphism. That is, _w_1(λ ⊗ μ) = _w_1(λ) + _w_1(μ) for all line bundles λ, μ → X.

For example, since _H_1(_S_1; Z/2Z) = Z/2Z, there are only two line bundles over the circle up to bundle isomorphism: the trivial one, and the open Möbius strip (i.e., the Möbius strip with its boundary deleted).

The same construction for complex vector bundles shows that the Chern class defines a bijection between complex line bundles over X and _H_2(X; Z), because the corresponding classifying space is P∞(C), a K(Z, 2). This isomorphism is true for topological line bundles, the obstruction to injectivity of the Chern class for algebraic vector bundles is the Jacobian variety.

Topological interpretation of vanishing

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wi(E) = 0 whenever i > rank(E).
If Ek has s 1 , … , s ℓ {\displaystyle s_{1},\ldots ,s_{\ell }} $s_{1},\ldots ,s_{\ell }$ sections which are everywhere linearly independent then the ℓ {\displaystyle \ell } $\ell$ top degree Whitney classes vanish: w k − ℓ + 1 = ⋯ = w k = 0 {\displaystyle w_{k-\ell +1}=\cdots =w_{k}=0} $w_{k-\ell +1}=\cdots =w_{k}=0$ .
The first Stiefel–Whitney class is zero if and only if the bundle is orientable. In particular, a manifold M is orientable if and only if _w_1(TM) = 0.
The bundle admits a spin structure if and only if both the first and second Stiefel–Whitney classes are zero.
For an orientable bundle, the second Stiefel–Whitney class is in the image of the natural map _H_2(M, Z) → _H_2(M, Z/2Z) (equivalently, the so-called third integral Stiefel–Whitney class is zero) if and only if the bundle admits a spinc structure.
All the Stiefel–Whitney numbers (see below) of a smooth compact manifold X vanish if and only if the manifold is the boundary of some smooth compact (unoriented) manifold (Note that some Stiefel-Whitney class could still be non-zero, even if all the Stiefel- Whitney numbers vanish!)

Uniqueness of the Stiefel–Whitney classes

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The bijection above for line bundles implies that any functor θ satisfying the four axioms above is equal to w, by the following argument. The second axiom yields θ(γ1) = 1 + θ1(γ1). For the inclusion map i : P1(R) → P∞(R), the pullback bundle i ∗ γ 1 {\displaystyle i^{*}\gamma ^{1}} $i^{*}\gamma ^{1}$ is equal to γ 1 1 {\displaystyle \gamma _{1}^{1}} $\gamma _{1}^{1}$ . Thus the first and third axiom imply

i ∗ θ 1 ( γ 1 ) = θ 1 ( i ∗ γ 1 ) = θ 1 ( γ 1 1 ) = w 1 ( γ 1 1 ) = w 1 ( i ∗ γ 1 ) = i ∗ w 1 ( γ 1 ) . {\displaystyle i^{*}\theta _{1}\left(\gamma ^{1}\right)=\theta _{1}\left(i^{*}\gamma ^{1}\right)=\theta _{1}\left(\gamma _{1}^{1}\right)=w_{1}\left(\gamma _{1}^{1}\right)=w_{1}\left(i^{*}\gamma ^{1}\right)=i^{*}w_{1}\left(\gamma ^{1}\right).} $i^{*}\theta _{1}\left(\gamma ^{1}\right)=\theta _{1}\left(i^{*}\gamma ^{1}\right)=\theta _{1}\left(\gamma _{1}^{1}\right)=w_{1}\left(\gamma _{1}^{1}\right)=w_{1}\left(i^{*}\gamma ^{1}\right)=i^{*}w_{1}\left(\gamma ^{1}\right).$

Since the map

i ∗ : H 1 ( P ∞ ( R ) ; Z / 2 Z ) → H 1 ( P 1 ( R ) ; Z / 2 Z ) {\displaystyle i^{*}:H^{1}\left(\mathbf {P} ^{\infty }(\mathbf {R} \right);\mathbf {Z} /2\mathbf {Z} )\to H^{1}\left(\mathbf {P} ^{1}(\mathbf {R} );\mathbf {Z} /2\mathbf {Z} \right)} $i^{*}:H^{1}\left(\mathbf {P} ^{\infty }(\mathbf {R} \right);\mathbf {Z} /2\mathbf {Z} )\to H^{1}\left(\mathbf {P} ^{1}(\mathbf {R} );\mathbf {Z} /2\mathbf {Z} \right)$

is an isomorphism, θ 1 ( γ 1 ) = w 1 ( γ 1 ) {\displaystyle \theta _{1}(\gamma ^{1})=w_{1}(\gamma ^{1})} $\theta _{1}(\gamma ^{1})=w_{1}(\gamma ^{1})$ and θ(γ1) = w(γ1) follow. Let E be a real vector bundle of rank n over a space X. Then E admits a splitting map, i.e. a map f : X′ → X for some space X′ such that f ∗ : H ∗ ( X ; Z / 2 Z ) ) → H ∗ ( X ′ ; Z / 2 Z ) {\displaystyle f^{*}:H^{*}(X;\mathbf {Z} /2\mathbf {Z} ))\to H^{*}(X';\mathbf {Z} /2\mathbf {Z} )} $f^{*}:H^{*}(X;\mathbf {Z} /2\mathbf {Z} ))\to H^{*}(X';\mathbf {Z} /2\mathbf {Z} )$ is injective and f ∗ E = λ 1 ⊕ ⋯ ⊕ λ n {\displaystyle f^{*}E=\lambda _{1}\oplus \cdots \oplus \lambda _{n}} $f^{*}E=\lambda _{1}\oplus \cdots \oplus \lambda _{n}$ for some line bundles λ i → X ′ {\displaystyle \lambda _{i}\to X'} $\lambda _{i}\to X'$ . Any line bundle over X is of the form g ∗ γ 1 {\displaystyle g^{*}\gamma ^{1}} $g^{*}\gamma ^{1}$ for some map g, and

θ ( g ∗ γ 1 ) = g ∗ θ ( γ 1 ) = g ∗ w ( γ 1 ) = w ( g ∗ γ 1 ) , {\displaystyle \theta \left(g^{*}\gamma ^{1}\right)=g^{*}\theta \left(\gamma ^{1}\right)=g^{*}w\left(\gamma ^{1}\right)=w\left(g^{*}\gamma ^{1}\right),} $\theta \left(g^{*}\gamma ^{1}\right)=g^{*}\theta \left(\gamma ^{1}\right)=g^{*}w\left(\gamma ^{1}\right)=w\left(g^{*}\gamma ^{1}\right),$

by naturality. Thus θ = w on Vect 1 ( X ) {\displaystyle {\text{Vect}}_{1}(X)} ${\text{Vect}}_{1}(X)$ . It follows from the fourth axiom above that

f ∗ θ ( E ) = θ ( f ∗ E ) = θ ( λ 1 ⊕ ⋯ ⊕ λ n ) = θ ( λ 1 ) ⋯ θ ( λ n ) = w ( λ 1 ) ⋯ w ( λ n ) = w ( f ∗ E ) = f ∗ w ( E ) . {\displaystyle f^{*}\theta (E)=\theta (f^{*}E)=\theta (\lambda _{1}\oplus \cdots \oplus \lambda _{n})=\theta (\lambda _{1})\cdots \theta (\lambda _{n})=w(\lambda _{1})\cdots w(\lambda _{n})=w(f^{*}E)=f^{*}w(E).} $f^{*}\theta (E)=\theta (f^{*}E)=\theta (\lambda _{1}\oplus \cdots \oplus \lambda _{n})=\theta (\lambda _{1})\cdots \theta (\lambda _{n})=w(\lambda _{1})\cdots w(\lambda _{n})=w(f^{*}E)=f^{*}w(E).$

Since f ∗ {\displaystyle f^{*}} $f^{*}$ is injective, θ = w. Thus the Stiefel–Whitney class is the unique functor satisfying the four axioms above.

Non-isomorphic bundles with the same Stiefel–Whitney classes

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Although the map w 1 : V e c t 1 ( X ) → H 1 ( X ; Z / 2 Z ) {\displaystyle w_{1}\colon \mathrm {Vect} _{1}(X)\to H^{1}(X;\mathbb {Z} /2\mathbb {Z} )} $w_{1}\colon \mathrm {Vect} _{1}(X)\to H^{1}(X;\mathbb {Z} /2\mathbb {Z} )$ is a bijection, the corresponding map is not necessarily injective in higher dimensions. For example, consider the tangent bundle T S n {\displaystyle TS^{n}} $TS^{n}$ for n even. With the canonical embedding of S n {\displaystyle S^{n}} $S^{n}$ in R n + 1 {\displaystyle \mathbb {R} ^{n+1}} $\mathbb {R} ^{n+1}$ , the normal bundle ν {\displaystyle \nu } $\nu$ to S n {\displaystyle S^{n}} $S^{n}$ is a line bundle. Since S n {\displaystyle S^{n}} $S^{n}$ is orientable, ν {\displaystyle \nu } $\nu$ is trivial. The sum T S n ⊕ ν {\displaystyle TS^{n}\oplus \nu } $TS^{n}\oplus \nu$ is just the restriction of T R n + 1 {\displaystyle T\mathbb {R} ^{n+1}} $T\mathbb {R} ^{n+1}$ to S n {\displaystyle S^{n}} $S^{n}$ , which is trivial since R n + 1 {\displaystyle \mathbb {R} ^{n+1}} $\mathbb {R} ^{n+1}$ is contractible. Hence w(TSn) = w(TSn)w(ν) = w(TSn ⊕ ν) = 1. But, provided n is even, TSn → Sn is not trivial; its Euler class e ( T S n ) = χ ( T S n ) [ S n ] = 2 [ S n ] ≠ 0 {\displaystyle e(TS^{n})=\chi (TS^{n})[S^{n}]=2[S^{n}]\not =0} $e(TS^{n})=\chi (TS^{n})[S^{n}]=2[S^{n}]\not =0$ , where [_Sn_] denotes a fundamental class of Sn and χ the Euler characteristic.

Stiefel–Whitney numbers

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If we work on a manifold of dimension n, then any product of Stiefel–Whitney classes of total degree n can be paired with the Z/2Z-fundamental class of the manifold to give an element of Z/2Z, a Stiefel–Whitney number of the vector bundle. For example, if the manifold has dimension 3, there are three linearly independent Stiefel–Whitney numbers, given by w 1 3 , w 1 w 2 , w 3 {\displaystyle w_{1}^{3},w_{1}w_{2},w_{3}} $w_{1}^{3},w_{1}w_{2},w_{3}$ . In general, if the manifold has dimension n, the number of possible independent Stiefel–Whitney numbers is the number of partitions of n.

The Stiefel–Whitney numbers of the tangent bundle of a smooth manifold are called the Stiefel–Whitney numbers of the manifold. They are known to be cobordism invariants. It was proven by Lev Pontryagin that if B is a smooth compact (n+1)–dimensional manifold with boundary equal to M, then the Stiefel-Whitney numbers of M are all zero.[1] Moreover, it was proved by René Thom that if all the Stiefel-Whitney numbers of M are zero then M can be realised as the boundary of some smooth compact manifold.[2]

One Stiefel–Whitney number of importance in surgery theory is the de Rham invariant of a (4_k_+1)-dimensional manifold, w 2 w 4 k − 1 . {\displaystyle w_{2}w_{4k-1}.} $w_{2}w_{4k-1}.$

The Stiefel–Whitney classes w k {\displaystyle w_{k}} $w_{k}$ are the Steenrod squares of the Wu classes v k {\displaystyle v_{k}} $v_{k}$ , defined by Wu Wenjun in 1947.[3] Most simply, the total Stiefel–Whitney class is the total Steenrod square of the total Wu class: Sq ⁡ ( v ) = w {\displaystyle \operatorname {Sq} (v)=w} $\operatorname {Sq} (v)=w$ . Wu classes are most often defined implicitly in terms of Steenrod squares, as the cohomology class representing the Steenrod squares. Let the manifold X be n dimensional. Then, for any cohomology class x of degree n − k {\displaystyle n-k} $n-k$ ,

v k ∪ x = Sq k ⁡ ( x ) {\displaystyle v_{k}\cup x=\operatorname {Sq} ^{k}(x)} $v_{k}\cup x=\operatorname {Sq} ^{k}(x)$ .

Or more narrowly, we can demand ⟨ v k ∪ x , μ ⟩ = ⟨ Sq k ⁡ ( x ) , μ ⟩ {\displaystyle \langle v_{k}\cup x,\mu \rangle =\langle \operatorname {Sq} ^{k}(x),\mu \rangle } $\langle v_{k}\cup x,\mu \rangle =\langle \operatorname {Sq} ^{k}(x),\mu \rangle$ , again for cohomology classes x of degree n − k {\displaystyle n-k} $n-k$ .[4]

Integral Stiefel–Whitney classes

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The element β w i ∈ H i + 1 ( X ; Z ) {\displaystyle \beta w_{i}\in H^{i+1}(X;\mathbf {Z} )} $\beta w_{i}\in H^{i+1}(X;\mathbf {Z} )$ is called the i + 1 integral Stiefel–Whitney class, where β is the Bockstein homomorphism, corresponding to reduction modulo 2, Z → Z/2Z:

β : H i ( X ; Z / 2 Z ) → H i + 1 ( X ; Z ) . {\displaystyle \beta \colon H^{i}(X;\mathbf {Z} /2\mathbf {Z} )\to H^{i+1}(X;\mathbf {Z} ).} $\beta \colon H^{i}(X;\mathbf {Z} /2\mathbf {Z} )\to H^{i+1}(X;\mathbf {Z} ).$

For instance, the third integral Stiefel–Whitney class is the obstruction to a Spinc structure.

Relations over the Steenrod algebra

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Over the Steenrod algebra, the Stiefel–Whitney classes of a smooth manifold (defined as the Stiefel–Whitney classes of the tangent bundle) are generated by those of the form w 2 i {\displaystyle w_{2^{i}}} $w_{2^{i}}$ . In particular, the Stiefel–Whitney classes satisfy the Wu formula, named for Wu Wenjun:[5]

S q i ( w j ) = ∑ t = 0 i ( j + t − i − 1 t ) w i − t w j + t . {\displaystyle Sq^{i}(w_{j})=\sum _{t=0}^{i}{j+t-i-1 \choose t}w_{i-t}w_{j+t}.} $Sq^{i}(w_{j})=\sum _{t=0}^{i}{j+t-i-1 \choose t}w_{i-t}w_{j+t}.$

Characteristic class for a general survey, in particular Chern class, the direct analogue for complex vector bundles
Real projective space

^ Pontryagin, Lev S. (1947). "Characteristic cycles on differentiable manifolds". Mat. Sbornik. New Series (in Russian). 21 (63): 233–284.
^ Milnor, John W.; Stasheff, James D. (1974). Characteristic Classes. Princeton University Press. pp. 50–53. ISBN 0-691-08122-0.
^ Wu, Wen-Tsün (1947). "Note sur les produits essentiels symétriques des espaces topologiques". Comptes Rendus Hebdomadaires des Séances de l'Académie des Sciences. 224: 1139–1141. MR 0019914.
^ Milnor, John W.; Stasheff, James D. (1974). Characteristic Classes. Princeton University Press. pp. 131–133. ISBN 0-691-08122-0.
^ (May 1999, p. 197)

Dale Husemoller, Fibre Bundles, Springer-Verlag, 1994.
May, J. Peter (1999), A Concise Course in Algebraic Topology (PDF), Chicago: University of Chicago Press, retrieved 2009-08-07
Milnor, John Willard (1970), "Algebraic _K_-theory and quadratic forms", Inventiones Mathematicae, 9, With an appendix by J. Tate: 318–344, doi:10.1007/BF01425486, ISSN 0020-9910, MR 0260844, Zbl 0199.55501
Wu class at the Manifold Atlas