Motivic zeta function

In algebraic geometry, the motivic zeta function of a smooth algebraic variety $X$ is the formal power series

Z(X,t)=\sum_{n=0}^\infty [X^{(n)}]t^n

Here $X^{(n)}$ is the $n$ -th symmetric power of $X$ , i.e., the quotient of $X^n$ by the action of the symmetric group $S_n$ , and $[X^{(n)}]$ is the class of $X^{(n)}$ in the ring of motives (see below).

If the ground field is finite, and one applies the counting measure to $Z(X,t)$ , one obtains the local zeta function of $X$ .

If the ground field is the complex numbers, and one applies Euler characteristic with compact supports to $Z(X,t)$ , one obtains $1/(1-t)^{\chi(X)}$ .

Motivic measures

A motivic measure is a map $\mu$ from the set of finite type schemes over a field $k$ to a commutative ring $A$ , satisfying the three properties

\mu(X)\,

depends only on the isomorphism class of

X

\mu(X)=\mu(Z)+\mu(X\setminus Z)

Z

is a closed subscheme of

X

\mu(X_1\times X_2)=\mu(X_1)\mu(X_2)

For example if $k$ is a finite field and $A={\Bbb Z}$ is the ring of integers, then $\mu(X)=\#(X(k))$ defines a motivic measure, the counting measure.

If the ground field is the complex numbers, then Euler characteristic with compact supports defines a motivic measure with values in the integers.

The zeta function with respect to a motivic measure $\mu$ is the formal power series in $A[[t]]$ given by

Z_\mu(X,t)=\sum_{n=0}^\infty\mu(X^{(n)})t^n

There is a universal motivic measure. It takes values in the K-ring of varieties, $A=K(V)$ , which is the ring generated by the symbols $[X]$ , for all varieties $X$ , subject to the relations

[X']=[X]\,

X'

and

X

are isomorphic,

[X]=[Z]+[X\setminus Z]

Z

is a closed subvariety of

X

[X_1\times X_2]=[X_1]\cdot[X_2]

The universal motivic measure gives rise to the motivic zeta function.

Examples

Let $\Bbb L=[{\Bbb A}^1]$ denote the class of the affine line.

Z({\Bbb A}^n,t)=\frac{1}{1-{\Bbb L}^n t}

Z({\Bbb P}^n,t)=\prod_{i=0}^n\frac{1}{1-{\Bbb L}^i t}

If $X$ is a smooth projective irreducible curve of genus $g$ admitting a line bundle of degree 1, and the motivic measure takes values in a field in which ${\Bbb L}$ is invertible, then

Z(X,t)=\frac{P(t)}{(1-t)(1-{\Bbb L}t)}\,,

where $P(t)$ is a polynomial of degree $2g$ . Thus, in this case, the motivic zeta function is rational. In higher dimension, the motivic zeta function is not always rational.

If $S$ is a smooth surface over an algebraically closed field of characteristic $0$ , then the generating function for the motives of the Hilbert schemes of $S$ can be expressed in terms of the motivic zeta function by Göttsche's Formula

\sum_{n=0}^\infty[S^{[n]}]t^n=\prod_{m=1}^\infty Z(S,{\Bbb L}^{m-1}t^m)

Here $S^{[n]}$ is the Hilbert scheme of length $n$ subschemes of $S$ . For the affine plane this formula gives

\sum_{n=0}^\infty[({\Bbb A}^2)^{[n]}]t^n=\prod_{m=1}^\infty \frac{1}{1-{\Bbb L}^{m+1}t^m}

This is essentially the partition function.