Ehrhart theory of cosmological polytopes
Abstract
The cosmological polytope of a graph G was recently introduced to give a geometric approach to the computation of wavefunctions for cosmological models with associated Feynman diagram G. Basic results in the theory of positive geometries dictate that this wavefunction may be computed as a sum of rational functions associated to the facets in a triangulation of the cosmological polytope. The normalized volume of the polytope then provides a complexity estimate for these computations. In this paper, we examine the (Ehrhart) h-polynomial of cosmological polytopes. We derive recursive formulas for computing the h-polynomial of disjoint unions and 1-sums of graphs. The degree of the h-polynomial for any G is computed and a characterization of palindromicity is given. Using these observations, a tight lower bound on the h-polynomial for any G is identified and explicit formulas for the h-polynomials of multitrees and multicycles are derived. The results generalize the existing results on normalized volumes of cosmological polytopes. A tight upper bound and a combinatorial formula for the h-polynomial of any cosmological polytope are conjectured.
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