An Eberhard-like theorem for pentagons and heptagons

Abstract

Eberhard proved that for every sequence (pk), 3 k r, k 5,7 of non-negative integers satisfying Euler's formula Σk3 (6-k) pk = 12, there are infinitely many values p6 such that there exists a simple convex polyhedron having precisely pk faces of length k for every k3, where pk=0 if k>r. In this paper we prove a similar statement when non-negative integers pk are given for 3 k r, except for k=5 and k=7. We prove that there are infinitely many values p5,p7 such that there exists a simple convex polyhedron having precisely pk faces of length k for every k3. %, where pk=0 if k>r. We derive an extension to arbitrary closed surfaces, yielding maps of arbitrarily high face-width. Our proof suggests a general method for obtaining results of this kind.