Topological K-theory

In mathematics, topological K-theory is a branch of algebraic topology. It was founded to study vector bundles on topological spaces, by means of ideas now recognised as (general) K-theory that were introduced by Alexander Grothendieck. The early work on topological K-theory is due to Michael Atiyah and Friedrich Hirzebruch.

Definitions

Let X be a compact Hausdorff space and ${\displaystyle k=\mathbb{ℝ}}$ or ${\displaystyle \mathbb{ℂ}}$. Then ${\displaystyle K_k(X)}$ is defined to be the Grothendieck group of the commutative monoid of isomorphism classes of finite-dimensional k-vector bundles over X under Whitney sum. Tensor product of bundles gives K-theory a commutative ring structure. Without subscripts, ${\displaystyle K(X)}$ usually denotes complex K-theory whereas real K-theory is sometimes written as ${\displaystyle KO(X)}$. The remaining discussion is focused on complex K-theory. As a first example, note that the K-theory of a point is the integers. This is because vector bundles over a point are trivial and thus classified by their rank and the Grothendieck group of the natural numbers is the integers. There is also a reduced version of K-theory, ${\displaystyle \tilde{K}(X)}$, defined for X a compact pointed space (cf. reduced homology). This reduced theory is intuitively K(X) modulo trivial bundles. It is defined as the group of stable equivalence classes of bundles. Two bundles E and F are said to be stably isomorphic if there are trivial bundles ${\displaystyle {\epsilon }_1}$ and ${\displaystyle {\epsilon }_2}$, so that ${\displaystyle E\oplus {\epsilon }_1\cong F\oplus {\epsilon }_2}$. This equivalence relation results in a group since every vector bundle can be completed to a trivial bundle by summing with its orthogonal complement. Alternatively, ${\displaystyle \tilde{K}(X)}$ can be defined as the kernel of the map ${\displaystyle K(X)\to K(x_0)\cong \mathbb{\mathbb{Z}}}$ induced by the inclusion of the base point x₀ into X. K-theory forms a multiplicative (generalized) cohomology theory as follows. The short exact sequence of a pair of pointed spaces (X, A)

${\displaystyle \tilde{K}(X/A)\to \tilde{K}(X)\to \tilde{K}(A)}$

extends to a long exact sequence

${\displaystyle \cdots \to \tilde{K}(SX)\to \tilde{K}(SA)\to \tilde{K}(X/A)\to \tilde{K}(X)\to \tilde{K}(A).}$

Let Sⁿ be the n-th reduced suspension of a space and then define

${\displaystyle {\tilde{K}}^{-n}(X):=\tilde{K}(S^{n}X),n\ge 0.}$

Negative indices are chosen so that the coboundary maps increase dimension. It is often useful to have an unreduced version of these groups, simply by defining:

${\displaystyle K^{-n}(X)={\tilde{K}}^{-n}(X_{+}).}$

Here ${\displaystyle X_{+}}$ is ${\displaystyle X}$ with a disjoint basepoint labeled '+' adjoined.^[1] Finally, the Bott periodicity theorem as formulated below extends the theories to positive integers.

Properties

• ${\displaystyle K^n}$ (respectively, ${\displaystyle {\tilde{K}}^n}$) is a contravariant functor from the homotopy category of (pointed) spaces to the category of commutative rings. Thus, for instance, the K-theory over contractible spaces is always ${\displaystyle \mathbb{\mathbb{Z}}.}$
• The spectrum of K-theory is ${\displaystyle BU\times \mathbb{\mathbb{Z}}}$ (with the discrete topology on ${\displaystyle \mathbb{\mathbb{Z}}}$), i.e. ${\displaystyle K(X)\cong [X_{+},\mathbb{\mathbb{Z}}\times BU],}$ where [ , ] denotes pointed homotopy classes and BU is the colimit of the classifying spaces of the unitary groups: ${\displaystyle BU(n)\cong \mathrm{Gr}(n,{\mathbb{ℂ}}^{\mathrm{\infty }}).}$ Similarly, $${\displaystyle \tilde{K}(X)\cong [X,\mathbb{\mathbb{Z}}\times BU].}$$ For real K-theory use BO.
• There is a natural ring homomorphism ${\displaystyle K^0(X)\to H^{2*}(X,\mathbb{\mathbb{Q}}),}$ the Chern character, such that ${\displaystyle K^0(X)\otimes \mathbb{\mathbb{Q}}\to H^{2*}(X,\mathbb{\mathbb{Q}})}$ is an isomorphism.
• The equivalent of the Steenrod operations in K-theory are the Adams operations. They can be used to define characteristic classes in topological K-theory.
• The Splitting principle of topological K-theory allows one to reduce statements about arbitrary vector bundles to statements about sums of line bundles.
• The Thom isomorphism theorem in topological K-theory is $${\displaystyle K(X)\cong \tilde{K}(T(E)),}$$ where T(E) is the Thom space of the vector bundle E over X. This holds whenever E is a spin-bundle.
• The Atiyah-Hirzebruch spectral sequence allows computation of K-groups from ordinary cohomology groups.
• Topological K-theory can be generalized vastly to a functor on C*-algebras, see operator K-theory and KK-theory.

Bott periodicity

The phenomenon of periodicity named after Raoul Bott (see Bott periodicity theorem) can be formulated this way:

• ${\displaystyle K(X\times {\mathbb{𝕊}}^2)=K(X)\otimes K({\mathbb{𝕊}}^2),}$ and ${\displaystyle K({\mathbb{𝕊}}^2)=\mathbb{\mathbb{Z}}[H]/(H-1{)}^2}$ where H is the class of the tautological bundle on ${\displaystyle {\mathbb{𝕊}}^2={\mathbb{\mathbb{P}}}^1(\mathbb{ℂ}),}$ i.e. the Riemann sphere.
• ${\displaystyle {\tilde{K}}^{n+2}(X)={\tilde{K}}^n(X).}$
• ${\displaystyle {\mathrm{\Omega }}^{2}BU\cong BU\times \mathbb{\mathbb{Z}}.}$

In real K-theory there is a similar periodicity, but modulo 8.

Applications

Topological K-theory has been applied in John Frank Adams’ proof of the “Hopf invariant one” problem via Adams operations.^[2] Adams also proved an upper bound for the number of linearly-independent vector fields on spheres.^[3]

Chern character

Michael Atiyah and Friedrich Hirzebruch proved a theorem relating the topological K-theory of a finite CW complex ${\displaystyle X}$ with its rational cohomology. In particular, they showed that there exists a homomorphism

${\displaystyle ch:K_{\text{top}}^{*}(X)\otimes \mathbb{\mathbb{Q}}\to H^{*}(X;\mathbb{\mathbb{Q}})}$

such that

${\displaystyle \begin{array}{rl}{K}_{\text{top}}^0(X)\otimes \mathbb{\mathbb{Q}}& \cong \underset{k}{⨁}{H}^{2k}(X;\mathbb{\mathbb{Q}})\\ K_{\text{top}}^1(X)\otimes \mathbb{\mathbb{Q}}& \cong \underset{k}{⨁}{H}^{2k+1}(X;\mathbb{\mathbb{Q}})\end{array}}$

There is an algebraic analogue relating the Grothendieck group of coherent sheaves and the Chow ring of a smooth projective variety ${\displaystyle X}$.

See also

• Atiyah–Hirzebruch spectral sequence (computational tool for finding K-theory groups)
• KR-theory
• Atiyah–Singer index theorem
• Snaith's theorem
• Algebraic K-theory

References

• Atiyah, Michael Francis (1989). K-theory. Advanced Book Classics (2nd ed.). Addison-Wesley. ISBN 978-0-201-09394-0. MR 1043170.
• Friedlander, Eric; Grayson, Daniel, eds. (2005). Handbook of K-Theory. Berlin, New York: Springer-Verlag. doi:10.1007/978-3-540-27855-9. ISBN 978-3-540-30436-4. MR 2182598.
• Karoubi, Max (1978). K-theory: an introduction. Classics in Mathematics. Springer-Verlag. doi:10.1007/978-3-540-79890-3. ISBN 0-387-08090-2.
• Karoubi, Max (2006). "K-theory. An elementary introduction". arXiv:math/0602082.
• Hatcher, Allen (2003). "Vector Bundles & K-Theory".
• Stykow, Maxim (2013). "Connections of K-Theory to Geometry and Topology".