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{{Short description|Mathematical functor in representation theory and algebraic topology}} {{Short description|Mathematical functor in representation theory and algebraic topology}}
In ], particularly in ] and ], a '''Mackey functor''' is a type of ] that generalizes various constructions in ] and ]. Named after ], these functors were first introduced by ] in 1971.<ref name="dress">Dress, A. W. M. (1971). "Notes on the theory of representations of finite groups. Part I: The Burnside ring of a finite group and some AGN-applications". Bielefeld.</ref><ref name="nlab">{{cite web|url=https://ncatlab.org/nlab/show/Mackey+functor|title=Mackey functor|website=]|access-date=January 3, 2025}}</ref> In ], particularly in ] and ], a '''Mackey functor''' is a type of ] that generalizes various constructions in ] and ]. Named after ] ] ], these functors were first introduced by ] mathematician ] in 1971.<ref name="dress">Dress, A. W. M. (1971). "Notes on the theory of representations of finite groups. Part I: The Burnside ring of a finite group and some AGN-applications". Bielefeld.</ref><ref name="nlab">{{cite web|url=https://ncatlab.org/nlab/show/Mackey+functor|title=Mackey functor|website=]|access-date=January 3, 2025}}</ref>


==Definition== ==Definition==
===Classical definition=== ===Classical definition===
Let <math>G</math> be a ]. A Mackey functor <math>M</math> for <math>G</math> consists of: Let <math>G</math> be a ]. A Mackey functor <math>M</math> for <math>G</math> consists of:
* For each ] <math>H \leq G</math>, an ] <math>M(H)</math> * For each ] <math>H \leq G</math>, an ] <math>M(H)</math>,
* For each pair of subgroups <math>H, K \leq G</math> with <math>H \subseteq K</math>: * For each pair of subgroups <math>H, K \leq G</math> with <math>H \subseteq K</math>:
** A ] <math>R^K_H: M(K) \to M(H)</math> ** A ] <math>R^K_H: M(K) \to M(H)</math>,
** A ] <math>I^K_H: M(H) \to M(K)</math> ** A ] <math>I^K_H: M(H) \to M(K)</math>.
These maps must satisfy the following axioms: These maps must satisfy the following axioms:
:'''Functoriality''': For nested subgroups <math>H \subseteq K \subseteq L</math>, <math>R^L_H = R^K_H \circ R^L_K</math> and <math>I^L_H = I^L_K \circ I^K_H</math>. :'''Functoriality''': For nested subgroups <math>H \subseteq K \subseteq L</math>, <math>R^L_H = R^K_H \circ R^L_K</math> and <math>I^L_H = I^L_K \circ I^K_H</math>.
:'''Conjugation''': For any <math>g \in G</math> and <math>H \leq G</math>, there are ] <math>c_g: M(H) \to M(gHg^{-1})</math> compatible with restriction and transfer. :'''Conjugation''': For any <math>g \in G</math> and <math>H \leq G</math>, there are ] <math>c_g: M(H) \to M(gHg^{-1})</math> compatible with restriction and transfer.
:'''] formula''': For subgroups <math>H, K \leq G</math>, the following identity holds: :'''] formula''': For subgroups <math>H, K \leq G</math>, the following identity holds:
::<math>R^G_H I^G_K = \sum_{x \in } I^H_{H \cap xKx^{-1}} \circ c_x \circ R^K_{x^{-1}Hx \cap K}</math>. ::<math>R^G_H I^G_K = \sum_{x \in } I^H_{H \cap xKx^{-1}} \circ c_x \circ R^K_{x^{-1}Hx \cap K}</math>.<ref name="dress"/>
===Modern definition=== ===Modern definition===
In modern ], a Mackey functor can be defined more elegantly using the language of ]. Let <math>\mathcal{C}</math> be a disjunctive <math>(\infty, 1)</math>-category and <math>\mathcal{A}</math> be an additive <math>(\infty, 1)</math>-category. A Mackey functor is a ] <math>M: \text{Span}(\mathcal{C}) \to \mathcal{A}</math> where <math>\text{Span}(\mathcal{C})</math> is the (,1)-category of correspondences in <math>\mathcal{C}</math>.<ref name="barwick">Barwick, C. (2017). "Spectral Mackey functors and equivariant algebraic K-theory (I)". ''Advances in Mathematics'', 304:646–727.</ref> In modern ], a Mackey functor can be defined more elegantly using the language of ]. Let <math>\mathcal{C}</math> be a disjunctive <math>(\infty, 1)</math>-category and <math>\mathcal{A}</math> be an additive <math>(\infty, 1)</math>-category (<math>(\infty, 1)</math>-categories are also known as ]). A Mackey functor is a ] <math>M: \text{Span}(\mathcal{C}) \to \mathcal{A}</math> where <math>\text{Span}(\mathcal{C})</math> is the <math>(\infty, 1)</math>-category of correspondences in <math>\mathcal{C}</math>.<ref name="barwick">Barwick, C. (2017). "Spectral Mackey functors and equivariant algebraic K-theory (I)". ''Advances in Mathematics'', 304:646–727.</ref>


==Applications== ==Applications==
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For a pointed G-CW complex <math>X</math> and a Mackey functor <math>A</math>, one can define ] ] with coefficients in <math>A</math> as: For a pointed G-CW complex <math>X</math> and a Mackey functor <math>A</math>, one can define ] ] with coefficients in <math>A</math> as:
:<math>H^n_G(X,A) := H^n(\text{Hom}(C_\bullet(X), A))</math> :<math>H^n_G(X,A) := H^n(\text{Hom}(C_\bullet(X), A))</math>
where <math>C_\bullet(X)</math> is the ] of Mackey functors given by stable equivariant homotopy groups of ]s.<ref name="kronholm">Kronholm, W. (2010). "The RO(G)-graded Serre spectral sequence". ''Homology, Homotopy and Applications'', 12(1):75-92.</ref> where <math>C_\bullet(X)</math> is the ] of Mackey functors given by stable equivariant ]s of ]s.<ref name="kronholm">Kronholm, W. (2010). "The RO(G)-graded Serre spectral sequence". ''Homology, Homotopy and Applications'', 12(1):75-92.</ref>


==References== ==References==

Latest revision as of 06:52, 6 January 2025

Mathematical functor in representation theory and algebraic topology

In mathematics, particularly in representation theory and algebraic topology, a Mackey functor is a type of functor that generalizes various constructions in group theory and equivariant homotopy theory. Named after American mathematician George Mackey, these functors were first introduced by German mathematician Andreas Dress in 1971.

Definition

Classical definition

Let G {\displaystyle G} be a finite group. A Mackey functor M {\displaystyle M} for G {\displaystyle G} consists of:

  • For each subgroup H G {\displaystyle H\leq G} , an abelian group M ( H ) {\displaystyle M(H)} ,
  • For each pair of subgroups H , K G {\displaystyle H,K\leq G} with H K {\displaystyle H\subseteq K} :

These maps must satisfy the following axioms:

Functoriality: For nested subgroups H K L {\displaystyle H\subseteq K\subseteq L} , R H L = R H K R K L {\displaystyle R_{H}^{L}=R_{H}^{K}\circ R_{K}^{L}} and I H L = I K L I H K {\displaystyle I_{H}^{L}=I_{K}^{L}\circ I_{H}^{K}} .
Conjugation: For any g G {\displaystyle g\in G} and H G {\displaystyle H\leq G} , there are isomorphisms c g : M ( H ) M ( g H g 1 ) {\displaystyle c_{g}:M(H)\to M(gHg^{-1})} compatible with restriction and transfer.
Double coset formula: For subgroups H , K G {\displaystyle H,K\leq G} , the following identity holds:
R H G I K G = x [ H G / K ] I H x K x 1 H c x R x 1 H x K K {\displaystyle R_{H}^{G}I_{K}^{G}=\sum _{x\in }I_{H\cap xKx^{-1}}^{H}\circ c_{x}\circ R_{x^{-1}Hx\cap K}^{K}} .

Modern definition

In modern category theory, a Mackey functor can be defined more elegantly using the language of spans. Let C {\displaystyle {\mathcal {C}}} be a disjunctive ( , 1 ) {\displaystyle (\infty ,1)} -category and A {\displaystyle {\mathcal {A}}} be an additive ( , 1 ) {\displaystyle (\infty ,1)} -category ( ( , 1 ) {\displaystyle (\infty ,1)} -categories are also known as quasi-categories). A Mackey functor is a product-preserving functor M : Span ( C ) A {\displaystyle M:{\text{Span}}({\mathcal {C}})\to {\mathcal {A}}} where Span ( C ) {\displaystyle {\text{Span}}({\mathcal {C}})} is the ( , 1 ) {\displaystyle (\infty ,1)} -category of correspondences in C {\displaystyle {\mathcal {C}}} .

Applications

In equivariant homotopy theory

Mackey functors play an important role in equivariant stable homotopy theory. For a genuine G {\displaystyle G} -spectrum E {\displaystyle E} , its equivariant homotopy groups form a Mackey functor given by:

π n ( E ) : G / H [ G / H + S n , X ] G {\displaystyle \pi _{n}(E):G/H\mapsto ^{G}}

where [ , ] G {\displaystyle ^{G}} denotes morphisms in the equivariant stable homotopy category.

Cohomology with Mackey functor coefficients

For a pointed G-CW complex X {\displaystyle X} and a Mackey functor A {\displaystyle A} , one can define equivariant cohomology with coefficients in A {\displaystyle A} as:

H G n ( X , A ) := H n ( Hom ( C ( X ) , A ) ) {\displaystyle H_{G}^{n}(X,A):=H^{n}({\text{Hom}}(C_{\bullet }(X),A))}

where C ( X ) {\displaystyle C_{\bullet }(X)} is the chain complex of Mackey functors given by stable equivariant homotopy groups of quotient spaces.

References

  1. ^ Dress, A. W. M. (1971). "Notes on the theory of representations of finite groups. Part I: The Burnside ring of a finite group and some AGN-applications". Bielefeld.
  2. "Mackey functor". nLab. Retrieved January 3, 2025.
  3. Barwick, C. (2017). "Spectral Mackey functors and equivariant algebraic K-theory (I)". Advances in Mathematics, 304:646–727.
  4. May, J. P. (1996). "Equivariant homotopy and cohomology theory". CBMS Regional Conference Series in Mathematics, vol. 91.
  5. Kronholm, W. (2010). "The RO(G)-graded Serre spectral sequence". Homology, Homotopy and Applications, 12(1):75-92.

Further reading

  • Dieck, T. (1987). Transformation Groups. de Gruyter. ISBN 978-3110858372
  • Webb, P. "A Guide to Mackey Functors"
  • Bouc, S. (1997). "Green Functors and G-sets". Lecture Notes in Mathematics 1671. Springer-Verlag.
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