On kernel isomorphisms of m-Cayley digraphs and finite 2PCI-groups

Abstract

The isomorphism problem for digraphs is a fundamental problem in graph theory. In this paper, we consider this problem for m-Cayley digraphs which are generalization of Cayley digraphs. Let m be a positive integer. A digraph admitting a group G of automorphisms acting semiregularly on the vertices with exactly m orbits is called an m-Cayley digraph of G. In our previous paper, we developed a theory for m-Cayley isomorphisms of m-Cayley digraphs, and classified finite mCI-groups for each m≥ 2, and finite mPCI-groups for each m≥ 4. The next natural step is to classify finite mPCI-groups for m=2 or 3. Note that BCI-groups form an important subclass of the 2PCI-groups, which were introduced in 2008 by Xu et al. Despite much effort having been made on the study of BCI-groups, the problem of classifying finite BCI-groups is still widely open. In this paper, we prove that every finite 2PCI-group is solvable, and its Sylow 3-subgroup is isomorphic to Z3, Z3× Z3 or Z9, and Sylow p-subgroup with p=3 is either elementary abelian, or isomorphic to Z4 or Q8. We also introduce the kernel isomorphisms of m-Cayley digraphs, and establish some useful theory for studying this kind of isomorphisms. Using the results of kernel isomorphisms of m-Cayley digraphs together with the results on 2PCI-groups, we give a proper description of finite BCI-groups, and in particular, we obtain a complete classification of finite non-abelian BCI-groups.