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 ${\displaystyle \pi :X\to S}$ to the fiber ${\displaystyle {\pi }^{-1}(s)}$ over a point ${\displaystyle s\in S}$.

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,

. If we have the topos of sheaves on a topological space

, denoted

, then to give a point

in

is equivalent to defining adjoint functors

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

The functor

sends a sheaf

on

to its fiber over the point

; that is, its stalk.^[2]

Consider the category of covering spaces over a topological space

, denoted

. Then, from a point

there is a fiber functor^[3]

${\displaystyle {\text{Fib}}_x:ℭ𝔬𝔳(X)\to 𝔖𝔢𝔱}$

sending a covering space

to the fiber

. This functor has automorphisms coming from

since the fundamental group acts on covering spaces on a topological space

. In particular, it acts on the set

. In fact, the only automorphisms of

come from

.

There is an algebraic analogue of covering spaces coming from the étale topology on a connected scheme

. The underlying site consists of finite étale covers, which are finite^[4][5] flat surjective morphisms

such that the fiber over every geometric point

is the spectrum of a finite étale

-algebra. For a fixed geometric point

, consider the geometric fiber

and let

be the underlying set of

-points. Then,

${\displaystyle {\text{Fib}}_{\bar{s}}:{𝔉𝔢𝔱}_S\to 𝔖𝔢𝔱𝔰}$

is a fiber functor where

is the topos from the finite étale topology on

. In fact, it is a theorem of Grothendieck that the automorphisms of

form a profinite group, denoted

, and induce a continuous group action on these finite fiber sets, giving an equivalence between covers and the finite sets with such actions.

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

• Topos
• Étale topology
• Motive (algebraic geometry)
• Anabelian geometry

• 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