Orbit counts and twist zeta functions of weighted projective stacks over finite fields
Abstract
Let Fq be a finite field and w=(w0,…,wn) a vector of positive integer weights. Several finite-field counts attached to the weighted projective space Pnw are easily conflated: the coarse rational-point count and the stacky mass are both weight-independent, whereas the number Aw(q) of Fq×-orbits on nonzero Fq-representatives for the weighted action depends on the weights. We prove the closed formula \[ Aw(q)=Σ S⊂eq\0,…,n\(q-1)|S|-1(kS,q-1), kS=\wi:i∈ S\, \] and identify Aw(q) intrinsically as the number of Fq-isomorphism classes of the weighted projective stack Pw=[( An+1\0\)/Gm] -- equivalently, the number of Fq-twists lying over the coarse points -- the discrepancy from the coarse count being governed by the Kummer groups Fq×/( Fq×)kS. We read the behaviour of Aw under reduction of the weight vector through the Fq-cohomology of the associated μd-gerbe, and prove that the twist zeta function Ztw(Pw,t)=(Σr1Aw(qr)tr/r) is rational with multiplicity spectrum independent of q, admitting a single global functional equation precisely when the weights share a common prime-to-p part -- for reduced w, precisely when the twist theory is trivial. For weighted diagonal hypersurfaces and same-degree pairs in the split regime, we compute the twist zeta function of the substack explicitly, with reciprocal roots given by Gauss sums and, for intersections, by Frobenius eigenvalues of superelliptic curves.
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