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In algebraic topology, a branch of mathematics, a ${\displaystyle G}$-spectrum for a finite group ${\displaystyle G}$ is an object representing an equivariant generalized cohomology theory. There are different models for ${\displaystyle G}$-spectra, but they all determine the same homotopy theory.

There are various versions of orthogonal G-spectra. The version presented here is the one used in the solution of the Kervaire invariant one problem^[1]. Intuitively an orthogonal G-spectrum is a G-space together with a collections of deloopings indexed by the representations of G.

Given two orthogonal G-representations V,W we let ${\displaystyle Iso(V,W)}$ be the space of (not necessarily G-equivariant) isometries from V to W. This is a G-space with the natural conjugation action. There is a G-equivariant vector bundle ${\displaystyle \xi (V,W)}$ over ${\displaystyle Iso(V,W)}$ whose fiber over ${\displaystyle i:V\to W}$ is the orthogonal complement of the image of i in W. There is a natural map of vector bundles ${\displaystyle \xi (V,W)\times \xi (W,U)\to \xi (V,U)}$ lying above the composition map ${\displaystyle Iso(V,W)\times Iso(W,U)\to Iso(V,U)}$. This data allows us to construct a category J_G enriched in G-spaces, whose objects are G-representations and such that ${\displaystyle Map_{J_{G}}(V,W)}$ is the Thom spaces ${\displaystyle Th(\xi (V,W))}$ of the vector bundle ${\displaystyle \xi (V,W)\to Iso(V,W)}$.

An orthogonal G-spectrum E is an enriched functor from ${\displaystyle J_{G}}$ to pointed G-spaces. Concretely it is the datum of

• For every finite-dimensional orthogonal G-representation V a pointed G-space E(V);
• For every pair of G-representations V,W a G-equivariant map

${\displaystyle \theta _{V,W}:Th(\xi (V,W))\wedge E(V)\to E(V')\,.}$

These maps are required to satisfy the obvious associativity and unitality constraints. The Thom space ${\displaystyle Th(\xi (V,W))}$ should be thought of as the "union" of ${\displaystyle S^{W-iV}}$ across all possible isometric embeddings i.

The category of orthogonal G-spectra has a natural Symmetric monoidal category given by the Day convolution using the direct sum monoidal structure in the source and the smash product of pointed G-spaces in the target. This product is called the smash product of G-spectra.

In analogy with the homotopy groups of a spectrum, we can define for every integer n the n-th homotopy Mackey functor of a G-spectrum E. It is the Mackey functor whose value on a G-set U is the colimit

${\displaystyle \pi _{k}^{U}(E)=\mathrm {colim} _{V\supseteq -k}[U_{+}\wedge S^{V+k},X_{V}]_{G}.}$

where V runs through all H-representations equipped with a subrepresentation isomorphic to the direct sum of -k copies of the trivial representation (this condition is empty when k≥0) and V+k is either the direct sum of V with k copies of the trivial representation (if k≥0) or the orthogonal complement of the aforementioned subrepresentation. Specializing to the case of an orbit U=G/H we can define the H-equivariant k-th homotopy group of E as

${\displaystyle \pi _{k}^{H}(E)=\mathrm {colim} _{V\supseteq -k}[S^{V+k},X_{V}]_{H}}$

A stable equivalence of G-spectra is a map of G-spectra inducing an isomorphism on all homotopy groups. The localization of the category of G-spectra is called the G-stable homotopy category.

There is also a variant of the homotopy groups using G-representations. For every virtual G-representation V the V-th homotopy group of a G-spectrum E is

${\displaystyle \pi _{V}(E)=[S^{V},E]_{G}\,.}$

Care needs to be taken that, unlike the homotopy Mackey functors, the RO(G)-indexed homotopy groups in general do not detect equivalences (that is the analogue of the Whitehead theorem is false)^[2]

Similarly to the nonequivariant case we can define for every spectrum E the corresponding homology and cohomology theory

${\displaystyle E_{*}X=\pi _{*}(E\wedge X),\qquad E^{*}X=\pi _{*}F(X,E)\,.}$

• For every pointed G-space X we can define its suspension spectrum as

${\displaystyle (\Sigma ^{\infty }X)(V)=S^{V}\wedge X}$

In particular the suspension spectrum of the zero sphere with trivial action is called the sphere spectrum and denoted by ${\displaystyle \mathbb {S} }$, as in the nonequivariant case.

• For every V=[V_0-V_1] virtual representation of G, we can define a representation sphere S^V as

${\displaystyle S^{V}(W)=\mathrm {colim} _{U\supseteq -W}\Omega ^{V_{1}\oplus U}(V_{0}\oplus U\oplus W)^{+}}$

where (...)

• For every Mackey functor M there is a G-spectrum HM such that

${\displaystyle \pi _{i}HM={\begin{cases}M&{\textrm {if}}\ \ i=0\\0&{\textrm {otherwise}}\end{cases}}}$

called the Eilenberg-MacLane G-spectrum of M. It represents equivariant cohomology with coefficients in M.

• There exists a C₂-spectrum KR called real K-theory spectrum representing KR-theory. It satisfies a form of Bott periodicity given by ${\displaystyle S^{\rho }\wedge KR\cong KR}$ where ρ is the regular representation of C₂.

For any G-spectrum E we can define the underlying space

${\displaystyle \Omega ^{\infty }E=\mathrm {hocolim} _{V}\Omega ^{V}E(V)}$

where the homotopy colimit is computed over the topological category of G-representations. More generally for every G-representation W we can write

${\displaystyle \Omega ^{\infty -W}E=\mathrm {hocolim} _{V}\Omega ^{V}E(V\oplus W)}$

so that

${\displaystyle \Omega ^{\infty }E\cong \Omega ^{W}(\Omega ^{\infty -W}E)\,.}$

Hence an orthogonal G-spectrum should be thought of as a G-space ${\displaystyle \Omega ^{\infty }E}$ together a family of deloopings for every G-representation (similarly to how a spectrum consists of a space together with a family of iterated deloopings).

If E is an orthogonal G-spectrum, its Lewis-May fixed points are the spectrum E^G whose n-space is (E^G)_n = E(\mathbb{R}^n)^G and with the maps...

An important observation is that the suspension spectra of finite G-sets span a subcategory of the G-equivariant stable homotopy category which is equivalent to the Burnside category. So the homotopy groups of a G-spectrum can be assemble to for an homotopy Mackey functor. In fact this is true even if we consider the topological subcategory provided we

Theorem (Guillou-May, Schwede-Shipley): The category of orthogonal G-spectra is equivalent to the category of additive topological functors from the Burnside category to spectra.

Under this point of view a lot of the constructions we have described above are evident. For example if E is a spectral Mackey functor its Lewis-May fixed points ${\displaystyle E^{H}}$ are simply the value of the spectral Mackey functor on the G-set G/H. The geometric fixed points instead are obtained as a left Kan extension ...

Let H be a subgroup of G. If E is an orthogonal H-spectrum we can define the norm as the G-spectrum

${\displaystyle N_{H}^{G}E(V)=\mathrm {hocolim} _{V}\Omega ^{\mathrm {ind} _{H}^{G}V}\Sigma ^{\infty }N_{H}^{G}(X(V))}$

Sometimes the name G-spectrum is used to mean a spectrum with an action of the group G. These objects form in fact a full subcategory of the category of G-spectra, corresponding to those E such that the map ${\displaystyle E^{H}\to E^{hH}}$ is an equivalence for every subgroup H.

• Hill, Micheal A.; Hopkins, Micheal J.; Ravenel, Douglas C. (2016). "On the nonexistence of elements of Kervaire invariant one". Annals of Mathematics. 184 (1): 1–262. doi:10.4007/annals.2016.184.1.1.
• Lewis, L. Gaunce; May, Peter; Steinberger, Mark (1986). Equivariant Stable Homotopy Theory. Springer Lecture Notes in Mathematics.