Moduli stack of principal bundles

In algebraic geometry, given a smooth projective curve X over a finite field $\mathbf{F}_q$ and a smooth affine group scheme G over it, the moduli stack of principal bundles over X, denoted by $\operatorname {Bun} _{G}(X)$ , is an algebraic stack given by:^[1] for any $\mathbf{F}_q$ -algebra R,

\operatorname{Bun}_G(X)(R) =

the category of principal G-bundles over the relative curve

X \times_{\mathbf{F}_q} \operatorname{Spec}R

.

In particular, the category of $\mathbf{F}_q$ -points of $\operatorname {Bun} _{G}(X)$ , that is, $\operatorname{Bun}_G(X)(\mathbf{F}_q)$ , is the category of G-bundles over X.

Similarly, $\operatorname {Bun} _{G}(X)$ can also be defined when the curve X is over the field of complex numbers. Roughly, in the complex case, one can define $\operatorname {Bun} _{G}(X)$ as the quotient stack of the space of holomorphic connections on X by the gauge group. Replacing the quotient stack (which is not a topological space) by a homotopy quotient (which is a topological space) gives the homotopy type of $\operatorname {Bun} _{G}(X)$ .

In the finite field case, it is not common to define the homotopy type of $\operatorname {Bun} _{G}(X)$ . But one can still define a (smooth) cohomology and homology of $\operatorname {Bun} _{G}(X)$ .

Basic properties

It is known that $\operatorname {Bun} _{G}(X)$ is a smooth stack of dimension $(g(X)-1)\dim G$ where $g(X)$ is the genus of X. It is not of finite type but of locally of finite type; one thus usually uses a stratification by open substacks of finite type (cf. the Harder–Narasimhan stratification.) If G is a split reductive group, then the set of connected components $\pi_0(\operatorname{Bun}_G(X))$ is in a natural bijection with the fundamental group $\pi _{1}(G)$ .^[2]

The Atiyah–Bott formula

Behrend's trace formula

This is a (conjectural) version of the Lefschetz trace formula for $\operatorname {Bun} _{G}(X)$ when X is over a finite field, introduced by Behrend in 1993.^[3] It states:^[4] if G is a smooth affine group scheme with semisimple connected generic fiber, then

\# \operatorname{Bun}_G(X)(\mathbf{F}_q) = q^{\dim \operatorname{Bun}_G(X)} \operatorname{tr} (\phi^{-1}|H^*(\operatorname{Bun}_G(X); \mathbb{Z}_l))

where (see also Behrend's trace formula for the details)

l is a prime number that is not p and the ring $\mathbb{Z}_l$ of l-adic integers is viewed as a subring of $\mathbb {C}$ .
$\phi$ is the geometric Frobenius.
$\# \operatorname{Bun}_G(X)(\mathbf{F}_q) = \sum_P {1 \over \# \operatorname{Aut}(P)}$ , the sum running over all isomorphism classes of G-bundles on X and convergent.
$\operatorname{tr}(\phi^{-1}|V_*) = \sum_{i = 0}^\infty (-1)^i \operatorname{tr}(\phi^{-1}|V_i)$ for a graded vector space $V_*$ , provided the series on the right absolutely converges.

A priori, neither left nor right side in the formula converges. Thus, the formula states that the two sides converge to finite numbers and that those numbers coincide.

Notes

↑ http://www.math.harvard.edu/~lurie/283notes/Lecture2-FunctionFields.pdf
↑ Heinloth 2010, Proposition 2.1.2
↑ http://www.math.ubc.ca/~behrend/thesis.pdf
↑ Lurie 2014, Conjecture 1.3.4.

References

J. Heinloth, Lectures on the moduli stack of vector bundles on a curve, 2009 preliminary version
J. Heinloth, A.H.W. Schmitt, The Cohomology Ring of Moduli Stacks of Principal Bundles over Curves, 2010 preprint, available at http://www.uni-essen.de/~hm0002/.
Gaitsgory, D; Lurie, J.; Weil's Conjecture for Function Fields. 2014,