G-spectrum: Difference between revisions

In algebraic topology, a G-spectrum is a spectrum with an action of a (finite) group.

Let X be a spectrum with an action of a finite group G. The important notion is that of the homotopy fixed point set ${\displaystyle X^{hG}}$. There is always

${\displaystyle X^G\to X^{hG},}$

a map from the fixed point spectrum to a homotopy fixed point spectrum (because, by definition, ${\displaystyle X^{hG}}$ is the mapping spectrum ${\displaystyle F(B{G}_{+},X{)}^G}$).

Example: ${\displaystyle \mathbb{Z}/2}$ acts on the complex K-theory KU by taking the conjugate bundle of a complex vector bundle. Then ${\displaystyle K{U}^{h\mathbb{Z}/2}=KO}$, the real K-theory.

The cofiber of ${\displaystyle X_{hG}\to X^{hG}}$ is called the Tate spectrum of X.

This notion is due to J. Rognes Template:Harv. Let A be an E_∞-ring with an action of a finite group G and B = A^hG its invariant subring. Then B → A (the map of B-algebras in E_∞-sense) is said to be a G-Galois extension if the natural map

${\displaystyle A{\otimes }_{B}A\to \prod _{g\in G}A}$

(which generalizes ${\displaystyle x\otimes y\mapsto (g(x)y)}$ in the classical setup) is an equivalence. The extension is faithful if the Bousfield classes of A, B over B are equivalent.

Example: KO → KU is a ${\displaystyle \mathbb{Z}}$./2-Galois extension.

• Segal conjecture

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