For a simple finite graph G denote by the number of ways of partitioning the vertex set of G into k non-empty independent sets (that is, into classes that span no edges of G). If is the graph on n vertices with no edges then coincides with , the ordinary Stirling number of the second kind, and so we refer to as a graph Stirling number. Harper showed that the sequence of Stirling numbers of the second kind, and thus the graph Stirling sequence of , is asymptotically normal-essentially, as n grows, the histogram of , suitably normalized, approaches the density function of the standard normal distribution. In light of Harper's result, it is natural to ask for which sequences of graphs is there asymptotic normality of . Thanh and Galvin conjectured that if for each n, is acyclic and has n vertices, then asymptotic normality occurs, and they gave a proof under the added condition that has no more than components. Here we settle Thanh and Galvin's conjecture in the affirmative, and significantly extend it, replacing "acyclic" in their conjecture with "co-chromatic with a quasi-threshold graph, and with negligible chromatic number". Our proof combines old work of Navon and recent work of Engbers, Galvin and Hilyard on the normal order problem in the Weyl algebra, and work of Kahn on the matching polynomial of a graph.

• 出版日期2016-3