A Closer Look at Chapoton's q-Ehrhart Polynomials

Abstract

If P is a lattice polytope (i.e., P is the convex hull of finitely many integer points in Rd), Ehrhart's famous theorem (1962) asserts that the integer-point counting function |t P Zd| is a polynomial in the integer variable t. Chapoton (2016) proved that, given a fixed integral form λ: Zd Z, there exists a polynomial chaPλ(q,x) ∈ Q(q)[x] such that the refined enumeration function Σ m ∈ t P q λ(m) equals the evaluation chaPλ (q, [t]q) where, as usual, [t]q := qt - 1 q-1 ; naturally, for q=1 we recover the Ehrhart polynomial. Our motivating goal is to view Chapoton's work through the lens of Brion's Theorem (1988), which expresses the integer-point structure of a given polytope via that of its vertex cones. It turns out that this viewpoint naturally yields various refinements and extensions of Chapoton's results, including explicit formulas for chaPλ(q,x), its leading coefficient, and its behavior as t ∞. We also prove an analogue of Chapoton's structural and reciprocity theorems for rational polytopes (i.e., with vertices in Qd).