Ultra log-concavity and real-rootedness of dependence polynomials

Abstract

For some positive integer m, a real polynomial P(x)=Σk=0makxk with ak≥slant 0 is called log-concave (resp. ultra log-concave) if ak2≥slant ak-1ak+1 (resp. ak2≥slant (1+1k)(1+1m-k)· ak-1ak+1) for all 1≤slant k≤slant m-1. If P(x) has only real roots, then it is called real-rooted. It is well-known that the conditions of log-concavity, ultra log-concavity and real-rootedness are ever-stronger. For a graph G, a dependent set is a set of vertices which is not independent, i.e., the set of vertices whose induced subgraph contains at least one edge. The dependence polynomial of G is defined as D(G, x):=Σk≥slant 0dk(G)xk, where dk(G) is the number of dependent sets of size k in G. Horrocks proved that D(G, x) is log-concave for every graph G [J. Combin. Theory, Ser. B, 84 (2002) 180--185]. In the present paper, we prove that, for a graph G, D(G, x) is ultra log-concave if G is (K2 2K1)-free or contains an independent set of size |V(G)|-2, and give the characterization of graphs whose dependence polynomials are real-rooted. Finally, we focus more attention to the problems of log-concavity about independence systems and pose several conjectures closely related the famous Mason's Conjecture.