Spanning tree packing and 2-essential edge-connectivity
Abstract
An edge (vertex) cut of is -essential if has two components each of which has at least edges. A graph is -essentially -edge-connected (resp. -connected) if it has no -essential edge (resp. vertex) cuts of size less than . If , we simply call it essential. Recently, Lai and Li proved that every -edge-connected essentially -edge-connected graph contains edge-disjoint spanning trees, where are positive integers such that and . In this paper, we show that every -edge-connected and -essentially -edge-connected graph that is not a or a fat-triangle with multiplicity less than has edge-disjoint spanning trees, where and Extending Zhan's result, we also prove that every 3-edge-connected essentially 5-edge-connected and -essentially 8-edge-connected graph has two edge-disjoint spanning trees. As an application, this gives a new sufficient condition for Hamilton-connectedness of line graphs. In 2012, Kaiser and Vr\'ana proved that every 5-connected line graph of minimum degree at least 6 is Hamilton-connected. We allow graphs to have minimum degree 5 and prove that every 5-connected essentially 8-connected line graph is Hamilton-connected.
Keywords
Cite
@article{arxiv.2208.12922,
title = {Spanning tree packing and 2-essential edge-connectivity},
author = {Xiaofeng Gu and Runrun Liu and Gexin Yu},
journal= {arXiv preprint arXiv:2208.12922},
year = {2022}
}