Quotient stack

In algebraic geometry, a quotient stack is a stack that parametrizes equivariant objects. Geometrically, it generalizes a quotient of a scheme or a variety by a group: a quotient variety, say, would be a coarse approximation of a quotient stack.

The notion is of fundamental importance in the study of stacks: a stack that arises in nature is often either a quotient stack itself or admits a stratification by quotient stacks (e.g., a Deligne–Mumford stack.) A quotient stack is also used to construct other stacks like classifying stacks.

Definition

A quotient stack is defined as follows. Let G be an affine smooth group scheme over a scheme S and X an S-scheme on which G acts. Let the quotient stack $[X/G]$ be the category over the category of S-schemes, where

an object over T is a principal G-bundle $P\to T$ together with equivariant map $P\to X$ ;
a morphism from $P\to T$ to $P'\to T'$ is a bundle map (i.e., forms a commutative diagram) that is compatible with the equivariant maps $P\to X$ and $P'\to X$ .

Suppose the quotient $X/G$ exists as an algebraic space (for example, by the Keel–Mori theorem). The canonical map

[X/G]\to X/G

,

that sends a bundle P over T to a corresponding T-point,^[1] need not be an isomorphism of stacks; that is, the space "X/G" is usually coarser. The canonical map is an isomorphism if and only if the stabilizers are trivial (in which case $X/G$ exists.)^{[citation needed]}

In general, $[X/G]$ is an Artin stack (also called algebraic stack). If the stabilizers of the geometric points are finite and reduced, then it is a Deligne–Mumford stack.

Burt Totaro (2004) has shown: let X be a normal Noetherian algebraic stack whose stabilizer groups at closed points are affine. Then X is a quotient stack if and only if it has the resolution property; i.e., every coherent sheaf is a quotient of a vector bundle. Earlier, Robert Wayne Thomason proved that a quotient stack has the resolution property.

Remark: It is possible to approach the construction from the point of view of simplicial sheaves.^[2] See also: simplicial diagram.

Examples

An effective quotient orbifold, e.g., $[M/G]$ where the $G$ action has only finite stabilizers on the smooth space $M$ , is an example of a quotient stack.^[3]

If $X=S$ with trivial action of $G$ (often $S$ is a point), then $[S/G]$ is called the classifying stack of $G$ (in analogy with the classifying space of $G$ ) and is usually denoted by $BG$ . Borel's theorem describes the cohomology ring of the classifying stack.

Moduli of line bundles

One of the basic examples of quotient stacks comes from the moduli stack $B\mathbb {G} _{m}$ of line bundles $[*/\mathbb {G} _{m}]$ over ${\text{Sch}}$ , or $[S/\mathbb {G} _{m}]$ over ${\text{Sch}}/S$ for the trivial $\mathbb {G} _{m}$ -action on $S$ . For any scheme (or $S$ -scheme) $X$ , the $X$ -points of the moduli stack are the groupoid of principal $\mathbb {G} _{m}$ -bundles $P\to X$ .

Moduli of line bundles with n-sections

There is another closely related moduli stack given by $[\mathbb {A} ^{n}/\mathbb {G} _{m}]$ which is the moduli stack of line bundles with $n$ -sections. This follows directly from the definition of quotient stacks evaluated on points. For a scheme $X$ , the $X$ -points are the groupoid whose objects are given by the set

$[\mathbb {A} ^{n}/\mathbb {G} _{m}](X)=\left\{{\begin{matrix}P&\to &\mathbb {A} ^{n}\\\downarrow &&\\X\end{matrix}}:{\begin{aligned}&P\to \mathbb {A} ^{n}{\text{ is }}\mathbb {G} _{m}{\text{ equivariant and}}\\&P\to X{\text{ is a principal }}\mathbb {G} _{m}{\text{-bundle}}\end{aligned}}\right\}$

The morphism in the top row corresponds to the $n$ -sections of the associated line bundle over $X$ . This can be found by noting giving a $\mathbb {G} _{m}$ -equivariant map $\phi :P\to \mathbb {A} ^{1}$ and restricting it to the fiber $P|_{x}$ gives the same data as a section $\sigma$ of the bundle. This can be checked by looking at a chart and sending a point $x\in X$ to the map $\phi _{x}$ , noting the set of $\mathbb {G} _{m}$ -equivariant maps $P|_{x}\to \mathbb {A} ^{1}$ is isomorphic to $\mathbb {G} _{m}$ . This construction then globalizes by gluing affine charts together, giving a global section of the bundle. Since $\mathbb {G} _{m}$ -equivariant maps to $\mathbb {A} ^{n}$ is equivalently an $n$ -tuple of $\mathbb {G} _{m}$ -equivariant maps to $\mathbb {A} ^{1}$ , the result holds.

Moduli of formal group laws

Example:^[4] Let L be the Lazard ring; i.e., $L=\pi _{*}\operatorname {MU}$ . Then the quotient stack $[\operatorname {Spec} L/G]$ by $G$ ,

G(R)=\{g\in R[\![t]\!]|g(t)=b_{0}t+b_{1}t^{2}+\cdots ,b_{0}\in R^{\times }\}

,

is called the moduli stack of formal group laws, denoted by ${\mathcal {M}}_{\text{FG}}$ .

References

^ The T-point is obtained by completing the diagram $T\leftarrow P\to X\to X/G$ .
^ Jardine, John F. (2015). Local homotopy theory. Springer Monographs in Mathematics. New York: Springer-Verlag. section 9.2. doi:10.1007/978-1-4939-2300-7. MR 3309296.
^ "Definition 1.7". Orbifolds and Stringy Topology. Cambridge Tracts in Mathematics. p. 4.
^ Taken from http://www.math.harvard.edu/~lurie/252xnotes/Lecture11.pdf