Elementary examples • Every sheaf \mathcal{F}:C^{op} \to Sets from a category C with a Grothendieck topology can canonically be turned into a stack. For an object X \in \text{Ob}(C), instead of a set \mathcal{F}(X) there is a groupoid whose objects are the elements of \mathcal{F}(X) and the arrows are the identity morphism. • More concretely, let h be a contravariant functor :h: (Sch/S)^{op} \to Sets :Then, this functor
determines the following category H :# an object is a pair (X\to S, x) consisting of a scheme X in (Sch/S)^{op} and an element x \in h(X) :# a morphism (X\to S, x) \to (Y\to S,y) consists of a morphism \phi:X \to Y in (Sch/S) such that h(\phi)(y) = x. :Via the forgetful functor p:H \to (Sch/S), the category H is a
category fibered over (Sch/S). For example, if X is a scheme in (Sch/S), then it determines the contravariant functor h = \operatorname{Hom}(-, X) and the corresponding fibered category is the '
. Stacks (or prestacks) can be constructed as a variant of this construction. In fact, any scheme X with a quasi-compact diagonal is an algebraic stack associated to the scheme' X.
Stacks of objects • A
group-stack. • The
moduli stack of vector bundles: the category of vector bundles
V→
S is a stack over the category of topological spaces
S. A morphism from
V→
S to
W→
T consists of continuous maps from
S to
T and from
V to
W (linear on fibers) such that the obvious square commutes. The condition that this is a fibered category follows because one can take pullbacks of vector bundles over continuous maps of topological spaces, and the condition that a descent datum is effective follows because one can construct a vector bundle over a space by gluing together vector bundles on elements of an open cover. • The stack of quasi-coherent sheaves on schemes (with respect to the
fpqc-topology and weaker topologies) • The stack of affine schemes on a base scheme (again with respect to the fpqc topology or a weaker one)
Constructions with stacks Stack quotients If X is a scheme (Sch/S) and G is a smooth
affine group scheme acting on X, then there is a
quotient algebraic stack [X/G], taking a scheme Y \to S to the groupoid of G-torsors over the S-scheme Y with G-equivariant maps to X. Explicitly, given a space X with a G-action, form the stack [X/G], which (intuitively speaking)
sends a space Y to the groupoid of pullback diagrams[X/G](Y) = \begin{Bmatrix} Z & \xrightarrow{\Phi} & X \\ \downarrow & & \downarrow \\ Y & \xrightarrow{\phi} & [X/G] \end{Bmatrix}where \Phi is a G-equivariant morphism of spaces and Z \to Y is a principal G-bundle. The morphisms in this category are just morphisms of diagrams where the arrows on the right-hand side are equal and the arrows on the left-hand side are morphisms of principal G-bundles.
Classifying stacks A special case of this when
X is a point gives the
classifying stack BG of a smooth affine group scheme
G: \textbf{B}G := [pt/G]. It is named so since the category \mathbf{B}G(Y), the fiber over
Y, is precisely the category \operatorname{Bun}_G(Y) of principal G-bundles over Y. Note that \operatorname{Bun}_G(Y) itself can be considered as a stack, the
moduli stack of principal G-bundles on Y. An important subexample from this construction is \mathbf{B}GL_n, which is the moduli stack of principal GL_n-bundles. Since the data of a principal GL_n-bundle is equivalent to the data of a rank n vector bundle, this is isomorphic to the
moduli stack of rank n vector bundles Vect_n.
Moduli stack of line bundles The moduli stack of line bundles is B\mathbb{G}_m since every line bundle is canonically isomorphic to a principal \mathbb{G}_m-bundle. Indeed, given a line bundle L over a scheme S, the relative spec\underline{\text{Spec}}_S(\text{Sym}_S(L^\vee)) \to Sgives a geometric line bundle. By removing the image of the zero section, one obtains a principal \mathbb{G}_m-bundle. Conversely, from the representation id:\mathbb{G}_m \to \text{Aut}(\mathbb{A}^1), the associated line bundle can be reconstructed.
Gerbes A
gerbe is a stack in groupoids that is locally nonempty, for example the trivial gerbe BG that assigns to each scheme the groupoid of principal G-bundles over the scheme, for some group G.
Relative spec and proj If
A is a quasi-coherent
sheaf of algebras in an algebraic stack
X over a scheme
S, then there is a stack Spec(
A) generalizing the construction of the spectrum Spec(
A) of a commutative ring
A. An object of Spec(
A) is given by an
S-scheme
T, an object
x of
X(
T), and a morphism of sheaves of algebras from
x*(
A) to the coordinate ring
O(
T) of
T. If
A is a quasi-coherent sheaf of graded algebras in an algebraic stack
X over a scheme
S, then there is a stack Proj(
A) generalizing the construction of the projective scheme Proj(
A) of a graded ring
A.
Moduli stacks Moduli of curves • studied the
moduli stack M1,1 of elliptic curves, and showed that its Picard group is cyclic of order 12. For elliptic curves over the
complex numbers the corresponding stack is similar to a quotient of the
upper half-plane by the action of the
modular group. • G; e.g. consider \mathbf{B}\mathbb{Z}/2 \coprod \mathbf{B}S_3. What should be done with this? -->The
moduli space of algebraic curves \mathcal{M}_g defined as a universal family of smooth curves of given
genus g does not exist as an
algebraic variety because in particular there are curves admitting nontrivial automorphisms. However there is a moduli stack \mathcal{M}_g, which is a good substitute for the non-existent fine moduli space of smooth genus g curves. More generally there is a moduli stack \mathcal{M}_{g,n} of genus g curves with n marked points. In general this is an algebraic stack, and is a Deligne–Mumford stack for g \geq 2 or g = 1, n \geq 1 or g = 0, n \geq 3 (in other words when the automorphism groups of the curves are finite). This moduli stack has a completion consisting of the moduli stack of stable curves (for given g and n), which is proper over Spec
Z. For example, \mathcal{M}_0 is the classifying stack B\text{PGL}(2) of the projective
general linear group. (There is a subtlety in defining \mathcal{M}_1, as one has to use algebraic spaces rather than schemes to construct it.)
Kontsevich moduli spaces Another widely studied class of moduli spaces are the
Kontsevich moduli spaces parameterizing the space of stable maps between curves of a fixed genus to a fixed space X whose image represents a fixed cohomology class. These moduli spaces are denoted\overline{\mathcal{M}}_{g,n}(X,\beta)and can have wild behavior, such as being reducible stacks whose components are non-equal dimension. For example, pg 30 is\textbf{WP}(a_0,\ldots, a_n) := [\mathbb {A}^{n}-\{0\} / \mathbb{G}_m]Taking the vanishing locus of a weighted polynomial in a line bundle f \in \Gamma(\textbf{WP}(a_0,\ldots, a_n),\mathcal{O}(a)) gives a stacky weighted
projective variety.
Stacky curves Stacky curves, or orbicurves, can be constructed by taking the stack quotient of a morphism of curves by the monodromy group of the cover over the generic points. For example, take a projective morphism\text{Proj}(\mathbb{C}[x,y,z]/(x^5 + y^5 + z^5)) \to \text{Proj}(\mathbb{C}[x,y])which is generically
etale. The stack quotient of the domain by \mu_5 gives a stacky \mathbb{P}^1 with stacky points that have stabilizer group \mathbb{Z}/5 at the fifth roots of unity in the x/y-chart. This is because these are the points where the cover ramifies.
Non-affine stack An example of a non-affine stack is given by the half-line with two stacky origins. This can be constructed as the colimit of two inclusion of [\mathbb{G}_m/ (\mathbb{Z}/2)] \to [\mathbb{A}^1/(\mathbb{Z}/2)]. ==Quasi-coherent sheaves on algebraic stacks==