English

On $\BCI$-groups and $\CI$-groups

Group Theory 2020-03-17 v1

Abstract

Let GG be a finite group and SS be a subset of G.G. A bi-Cayley graph \BCay(G,S)\BCay(G,S) is a simple and an undirected graph with vertex-set G×{1,2}G\times\{1,2\} and edge-set {{(g,1),(sg,2)}gG,sS}\{\{(g,1),(sg,2)\}\mid g\in G, s\in S\}. A bi-Cayley graph \BCay(G,S)\BCay(G,S) is called a \BCI\BCI-graph if for any bi-Cayley graph \BCay(G,T)\BCay(G,T), whenever \BCay(G,S)\BCay(G,T)\BCay(G,S)\cong\BCay(G,T) we have T=gSσT=gS^\sigma for some gGg\in G and σ\Aut(G).\sigma\in\Aut(G). A group GG is called a \BCI\BCI-group if every bi-Cayley graph of GG is a \BCI\BCI-graph. In this paper, we showed that every \BCI\BCI-group is a \CI\CI-group, which gives a positive answer to a conjecture proposed by Arezoomand and Taeri in \cite{arezoomand1}. Also we proved that there is no any non-Abelian 44-\BCI\BCI-simple group. In addition all \BCI\BCI-groups of order 2p2p, pp a prime, are characterized.

Keywords

Cite

@article{arxiv.2003.06624,
  title  = {On $\BCI$-groups and $\CI$-groups},
  author = {Asieh Sattari and Majid Arezoomand and Mohammad A. Iranmanesh},
  journal= {arXiv preprint arXiv:2003.06624},
  year   = {2020}
}

Comments

12 pages

R2 v1 2026-06-23T14:14:45.951Z