On cubic non-Cayley vertex-transitive graphs
In 1983, the second author [D. Marušič, Ars Combinatoria 16B (1983), 297–302] asked for which positive integers n there exists a non-Cayley vertex-transitive graph on n vertices. (The term non-Cayley numbers has later been given to such integers.) Motivated by this problem, Feng [Discrete Math 248 (2002), 265–269] asked to determine the smallest valency ϑ(n) among valencies of non-Cayley vertex-transitive graphs of order n. As cycles are clearly Cayley graphs, ϑ(n)⩾3 for any non-Cayley number n. In this paper a goal is set to determine those non-Cayley numbers n for which ϑ(n) = 3, and among the latter to determine those for which the generalized Petersen graphs are the only non-Cayley vertex-transitive graphs of order n. It is known that for a prime p every vertex-transitive graph of order p, p2 or p3 is a Cayley graph, and that, with the exception of the Coxeter graph, every cubic non-Cayley vertex-transitive graph of order 2p, 4p or 2p2 is a generalized Petersen graph. In this paper the next natural step is taken by proving that every cubic non-Cayley vertex-transitive graph of order 4p2, p>7 a prime, is a generalized Petersen graph. In addition, cubic non-Cayley vertex-transitive graphs of order 2pk, where p>7 is a prime and k⩽p, are characterized.