# Matching Connectivity: On the Structure of Graphs with Perfect Matchings

**Authors:** Archontia C. Giannopoulou, Stephan Kreutzer, Sebastian Wiederrecht

arXiv: 1704.00493 · 2019-02-25

## TL;DR

This paper introduces matching connectivity as a new graph connectivity concept based on perfect matchings, generalizes existing results, and explores its properties and implications for n-extendable graphs.

## Contribution

It generalizes a key bipartite graph result to broader classes, defines matching connectivity, and establishes its relationship with n-extendable graphs.

## Key findings

- Proves a Menger-type theorem for matching n-connected graphs.
- Shows every n-extendable graph is matching n-connected.
- Characterizes graphs that are (n+1)-matching connected.

## Abstract

We introduce the concept of matching connectivity as a notion of connectivity in graph admitting perfect matchings which heavily relies on the structural properties of those matchings. We generalise a result of Robertson, Seymour and Thomas for bipartite graphs with perfect matchings (see [Neil Roberts, Paul D Seymour, and Robin Thomas. Permanents, pfaffian orientations, and even directed curcuits. Annals of Mathematics, 150(2):929-975, 1999]) in order to obtain a concept of alternating paths that turns out to be sufficient for the description of our connectivity parameter. We introduce some basic properties of matching connectivity and prove a Menger-type result for matching n-connected graphs. Furthermore, we show that matching connectivity fills a gap in the investigation of n-extendable graphs and their connectivity properties. To be more precise we show that every n-extendable graph is matching n-connected and for the converse every matching (n+1)-connected graph either is n-extendable, or belongs to a well described class of graphs: the brace h-critical graphs.

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Source: https://tomesphere.com/paper/1704.00493