On the structure of self-complementary graphs
Abstract
A \emph{self-complementary} graph is a graph isomorphic to its complement. An isomorphism between and its complement, viewed as a permutation of , is then called an \emph{antimorphism}. A \emph{skew partition} of is a partition of into 4 sets such that there is no edge between and every possible edge between . A \emph{symmetric partition} of is a partition of into 4 sets such that there is no edge between , no edge between , every possible edge between and every possible edge between . We give a new proof of a theorem of Gibbs saying that every self-complementary graph on vertices has disjoint paths on 4 vertices as induced subgraph. This new proof gives more structural information than the original one. We conjecture that every self-complementary graph on vertices either has an induced cycle on 5 vertices, or a skew partition, or a symmetric partition. The new proof of Gibb's theorem yields a proof of the conjecture for the self-complementary graphs that have an antimorphism that is the product of a two circular permutations, one of them of length 4.
Cite
@article{arxiv.1308.6139,
title = {On the structure of self-complementary graphs},
author = {Nicolas Trotignon},
journal= {arXiv preprint arXiv:1308.6139},
year = {2013}
}
Comments
Unpublished