Deligne–Mumford stack

In algebraic geometry, a DeligneÃ¢ÂÂMumford stack is a stack that behaves, in many respects, like an algebraic variety or an orbifold, while still allowing mild stacky phenomena such as finite stabilizer groups. More precisely, a stack over schemes is DeligneÃ¢ÂÂMumford if its diagonal is sufficiently well behaved and if it admits an ÃÂ©tale surjective cover by a scheme (an atlas).

Pierre Deligne and David Mumford introduced this notion in their 1969 paper on the irreducibility of the moduli space of algebraic curves, where they showed that the moduli stack of stable curves of fixed arithmetic genus is a proper smooth DeligneÃ¢ÂÂMumford stack over . Since then, DeligneÃ¢ÂÂMumford stacks have become a basic tool in moduli theory and in modern intersection theory, for instance in GromovÃ¢ÂÂWitten theory.

Definition

Let be a base scheme, and let F be a stack on . The stack F is called a DeligneÃ¢ÂÂMumford stack if the following conditions hold:

The diagonal morphism is representable, quasi-compact and separated.
There exists a scheme U and a representable, surjective, ÃÂ©tale morphism called an atlas (or cover) of F.

Many authors formulate the definition in the context of algebraic stacks by additionally requiring that F be an algebraic stack (in the sense of Michael Artin). In such formulations, a DeligneÃ¢ÂÂMumford stack is an algebraic stack whose diagonal is unramified and which admits an ÃÂ©tale surjective atlas by a scheme.

Relation with other notions

Algebraic stacks and Artin stacks

If, in the definition above, the word Ã¢ÂÂÃÂ©taleÃ¢ÂÂ is weakened to Ã¢ÂÂsmoothÃ¢ÂÂ, one obtains the notion of an algebraic stack (often called an Artin stack after Michael Artin). Thus every DeligneÃ¢ÂÂMumford stack is an algebraic (Artin) stack, but not conversely.

The condition that the atlas is ÃÂ©tale forces stabilizer groups to be finite and unramified over the base. In contrast, general Artin stacks may have positive-dimensional stabilizers, such as copies of or abelian varieties.

Algebraic spaces

An algebraic space can be regarded as a special case of a DeligneÃ¢ÂÂMumford stack, namely a DeligneÃ¢ÂÂMumford stack whose diagonal is an immersion and whose stabilizer groups are trivial. In this sense, algebraic spaces are Ã¢ÂÂnon-stackyÃ¢ÂÂ DeligneÃ¢ÂÂMumford stacks.

Orbifolds

Over the complex numbers, separated DeligneÃ¢ÂÂMumford stacks of finite type with finite stabilizers are often viewed as algebro-geometric analogues of orbifolds. More precisely, a smooth DeligneÃ¢ÂÂMumford stack over with finite stabilizers determines, and is determined by, a complex orbifold together with additional algebro-geometric structure.

Properties

Let F be a DeligneÃ¢ÂÂMumford stack that is quasi-compact and quasi-separated.

Finite stabilizers and automorphisms. For any quasi-compact scheme B and any object , the automorphism group of X over B is finite. Equivalently, the inertia stack of F is finite over F.
Coarse moduli spaces. If the inertia stack of F is finite (for example, if F is a separated DeligneÃ¢ÂÂMumford stack locally of finite type over a Noetherian base), then F admits a coarse moduli space in the sense of DeligneÃ¢ÂÂMumford, which is an algebraic space representing isomorphism classes of objects up to finite stabilizers.

Presentation by groupoids. Every DeligneÃ¢ÂÂMumford stack F admits a presentation by a groupoid in schemes. Concretely, if U Ã¢ÂÂ F is an ÃÂ©tale surjective atlas, then the fiber product defines a groupoid scheme whose associated quotient stack is equivalent to F. See groupoid scheme for details.
Local quotient structure. ÃÂtale-locally on the base, a DeligneÃ¢ÂÂMumford stack is a quotient of a scheme by a finite group action: for every point of F there is an ÃÂ©tale neighborhood over which F is equivalent to a quotient stack with G finite (often referred to as an orbifold chart).

Examples

Quotient by a finite group (affine stacks)

A basic way to construct DeligneÃ¢ÂÂMumford stacks is to take the stack quotient of a scheme or algebraic space by a finite group action with finite stabilizers. Let

be a cyclic group of order n acting on by

where is a primitive nth root of unity. The quotient stack

is then an affine smooth DeligneÃ¢ÂÂMumford stack: the stabilizer is trivial away from the origin, and equal to the full group at the origin, so all stabilizers are finite.

More generally, if a finite group G acts on a scheme X over a base scheme S in such a way that the action is ÃÂ©tale and the stabilizers are finite over S, then the quotient stack is a DeligneÃ¢ÂÂMumford stack over S.

Weighted projective stacks

Non-affine examples arise from weighted projective spaces and weighted projective varieties. For instance, the weighted projective line can be described as the quotient stack

where acts by

A point has a non-trivial stabilizer precisely when either or , in which case the stabilizer is a finite group of roots of unity (of order 2 or 3 respectively). Hence all stabilizers are finite and the quotient stack is DeligneÃ¢ÂÂMumford. Such stacks are sometimes referred to as weighted projective stacks or stacky projective lines.

Moduli stacks of curves

The prototypical examples of DeligneÃ¢ÂÂMumford stacks arise in the moduli theory of curves. For an integer , the moduli stack of smooth, proper, connected curves of genus g over schemes is an algebraic stack; its DeligneÃ¢ÂÂMumford compactification , obtained by allowing stable nodal curves, is a proper smooth DeligneÃ¢ÂÂMumford stack over .

More generally, the moduli stacks and of curves of genus g with n marked points are DeligneÃ¢ÂÂMumford stacks, and their geometry plays a central role in modern enumerative geometry and intersection theory.

Stacky curves

A stacky curve is, roughly speaking, a connected, one-dimensional, separated DeligneÃ¢ÂÂMumford stack of finite type over an algebraically closed field, with generically trivial stabilizer. Such objects generalize smooth projective curves by allowing finitely many stacky points with non-trivial finite stabilizer groups. Weighted projective lines and certain orbifold curves arising in representation theory and arithmetic geometry provide basic examples.

Non-example

A simple example of an algebraic stack that is not DeligneÃ¢ÂÂMumford is the classifying stack of the multiplicative group:

Here the stabilizer group at every point is isomorphic to , which is infinite and has positive dimension. Thus the diagonal is not unramified and the stack fails to be DeligneÃ¢ÂÂMumford, although it is an Artin stack.

References