The m-partite digraphical representations of valency 3 of finite groups generated by two elements
Abstract
Let G be a finite group and m be an integer. We employ the notation gi to represent elements (g,i) in the Cartesian product G × Zm, where Zm denotes integers modulo m. For given sets Ti,j ⊂eq G (i,j ∈ Zm), we construct the m-Cayley digraph = Cay(G, Ti,j: i,j ∈ Zm) with vertex set i∈ZmGi (where Gi = \gi | g ∈ G\) and arc set i,j\(gi, (tg)j) | t ∈ Ti,j, g ∈ G\. When Ti,i = for all i ∈ Zm, we call an m-partite Cayley digraph. For m-partite Cayley digraphs, we observe that a 1-partite Cayley digraph is necessarily an empty graph. Therefore, throughout this paper, we restrict our consideration to the case where m ≥ 2. The digraph is regular if there exists a non-negative integer k such that every vertex has out-valency and in-valency equal to k. All digraphs considered in this paper are regular. We say a group G admits an m-partite digraphical representation (m-PDR for short) if there exists a regular m-partite Cayley digraph with Aut() G. Based on Du et al.'s complete classification of unrestricted m-PDRs du4 (2022), we focus on the unresolved valency-specific cases. In this paper, we investigate m-PDRs of valency 3 for groups generated by at most two elements, and establish a complete classification of nontrivial finite simple groups admitting m-PDRs of valency 3 with m≥2.
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