Fiber functor

Fiber functors in category theory, topology and algebraic geometry refer to several loosely related functors that generalise the functors taking a covering space $\pi \colon X\rightarrow S$ to the fiber $\pi ^{-1}(s)$ over a point $s\in S$ .

Definition[edit]

A fiber functor (or fibre functor) is a loose concept which has multiple definitions depending on the formalism considered. One of the main initial motivations for fiber functors comes from Topos theory.^[1] Recall a topos is the category of sheaves over a site. If a site is just a single object, as with a point, then the topos of the point is equivalent to the category of sets, ${\mathfrak {Set}}$ . If we have the topos of sheaves on a topological space $X$ , denoted ${\mathfrak {T}}(X)$ , then to give a point $a$ in $X$ is equivalent to defining adjoint functors

$a^{*}:{\mathfrak {T}}(X)\leftrightarrows {\mathfrak {Set}}:a_{*}$

The functor $a^{*}$ sends a sheaf ${\mathfrak {F}}$ on $X$ to its fiber over the point $a$ ; that is, its stalk.^[2]

From covering spaces[edit]

Consider the category of covering spaces over a topological space $X$ , denoted ${\mathfrak {Cov}}(X)$ . Then, from a point $x\in X$ there is a fiber functor^[3]

${\text{Fib}}_{x}:{\mathfrak {Cov}}(X)\to {\mathfrak {Set}}$

sending a covering space $\pi :Y\to X$ to the fiber $\pi ^{-1}(x)$ . This functor has automorphisms coming from $\pi _{1}(X,x)$ since the fundamental group acts on covering spaces on a topological space $X$ . In particular, it acts on the set $\pi ^{-1}(x)\subset Y$ . In fact, the only automorphisms of ${\text{Fib}}_{x}$ come from $\pi _{1}(X,x)$ .

With étale topologies[edit]

There is an algebraic analogue of covering spaces coming from the étale topology on a connected scheme $S$ . The underlying site consists of finite étale covers, which are finite^[4]^[5] flat surjective morphisms $X\to S$ such that the fiber over every geometric point $s\in S$ is the spectrum of a finite étale $\kappa (s)$ -algebra. For a fixed geometric point ${\overline {s}}:{\text{Spec}}(\Omega )\to S$ , consider the geometric fiber $X\times _{S}{\text{Spec}}(\Omega )$ and let ${\text{Fib}}_{\overline {s}}(X)$ be the underlying set of $\Omega$ -points. Then,

${\text{Fib}}_{\overline {s}}:{\mathfrak {Fet}}_{S}\to {\mathfrak {Sets}}$

is a fiber functor where ${\mathfrak {Fet}}_{S}$ is the topos from the finite étale topology on $S$ . In fact, it is a theorem of Grothendieck the automorphisms of ${\text{Fib}}_{\overline {s}}$ form a profinite group, denoted $\pi _{1}(S,{\overline {s}})$ , and induce a continuous group action on these finite fiber sets, giving an equivalence between covers and the finite sets with such actions.

From Tannakian categories[edit]

Another class of fiber functors come from cohomological realizations of motives in algebraic geometry. For example, the De Rham cohomology functor $H_{dR}$ sends a motive $M(X)$ to its underlying de-Rham cohomology groups $H_{dR}^{*}(X)$ .^[6]

References[edit]

^ Grothendieck, Alexander. "SGA 4 Exp IV" (PDF). pp. 46–54. Archived (PDF) from the original on 2020-05-01.
^ Cartier, Pierre. "A Mad Day's Work: From Grothendieck to Connes and Kontsevich – The Evolution of Concepts of Space and Symmetry" (PDF). p. 400 (12 in pdf). Archived (PDF) from the original on 5 Apr 2020.
^ Szamuely. "Heidelberg Lectures on Fundamental Groups" (PDF). p. 2. Archived (PDF) from the original on 5 Apr 2020.
^ "Galois Groups and Fundamental Groups" (PDF). pp. 15–16. Archived (PDF) from the original on 6 Apr 2020.
^ Which is required to ensure the étale map $X\to S$ is surjective, otherwise open subschemes of $S$ could be included.
^ Deligne; Milne. "Tannakian Categories" (PDF). p. 58.

External links[edit]

SGA 4 and SGA 4 IV
Motivic Galois group - https://web.archive.org/web/20200408142431/https://www.him.uni-bonn.de/fileadmin/him/Lecture_Notes/motivic_Galois_group.pdf

[1] Grothendieck, Alexander. "SGA 4 Exp IV" (PDF). pp. 46–54. Archived (PDF) from the original on 2020-05-01.

[2] Cartier, Pierre. "A Mad Day's Work: From Grothendieck to Connes and Kontsevich – The Evolution of Concepts of Space and Symmetry" (PDF). p. 400 (12 in pdf). Archived (PDF) from the original on 5 Apr 2020.

[3] Szamuely. "Heidelberg Lectures on Fundamental Groups" (PDF). p. 2. Archived (PDF) from the original on 5 Apr 2020.

[4] "Galois Groups and Fundamental Groups" (PDF). pp. 15–16. Archived (PDF) from the original on 6 Apr 2020.

[5] Which is required to ensure the étale map $X\to S$ is surjective, otherwise open subschemes of $S$ could be included.

[6] Deligne; Milne. "Tannakian Categories" (PDF). p. 58.

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