The number of Hamiltonian decompositions of regular graphs

Abstract

A Hamilton cycle in a graph is a cycle passing through every vertex of . A Hamiltonian decomposition of is a partition of its edge set into disjoint Hamilton cycles. One of the oldest results in graph theory is Walecki's theorem from the 19th century, showing that a complete graph Kn on an odd number of vertices n has a Hamiltonian decomposition. This result was recently greatly extended by K\"uhn and Osthus. They proved that every r-regular n-vertex graph with even degree r=cn for some fixed c>1/2 has a Hamiltonian decomposition, provided n=n(c) is sufficiently large. In this paper we address the natural question of estimating H(), the number of such decompositions of . Our main result is that H()=r(1+o(1))nr/2. In particular, the number of Hamiltonian decompositions of Kn is n(1-o(1))n2/2.