P\'olya enumeration theorems in algebraic geometry

Abstract

We generalize a formula due to Macdonald that relates the singular Betti numbers of Xn/G to those of X, where X is a compact manifold and G is any subgroup of the symmetric group Sn acting on Xn by permuting coordinates. Our result is completely axiomatic: in a general setting, given an endomorphism on the cohomology H(X), it explains how we can explicitly relate the Lefschetz series of the induced endomorphism on H(Xn)G to that of the given endomorphism on H(X) in the presence of the K\"unneth formula with respect to a cup product. For example, when X is a compact manifold, we take the Lefschetz series given by the singular cohomology with rational coefficients. On the other hand, when X is a projective variety over a finite field Fq, we use the l-adic \'etale cohomology with a suitable choice of prime number l. We also explain how our formula generalizes the P\'olya enumeration theorem, a classical theorem in combinatorics that counts colorings of a graph up to given symmetries, where X is taken to be a finite set of colors. When X is a smooth projective variety over C, our formula also generalizes a result of Cheah that relates the Hodge numbers of Xn/G to those of X. We will also see that our result generalizes the following facts: 1. the generating function of the Poincar\'e polynomials of symmetric powers of a compact manifold X is rational; 2. the generating function of the Hodge-Deligne polynomials of symmetric powers of a smooth projective variety X over C is rational; 3. the zeta series of a projective variety X over Fq is rational. We also prove analogous rationality results when we replace Sn with An, alternating groups.