An epsilon improvement to the asymptotic density of kcriticalgraphs Open Access
Larsen, Victor Olaf (2015)
Published
Abstract
Given a graph G the chromatic number, denoted X(G), is smallest number of colors necessary to color V (G) such that no adjacent vertices receive the same color. A graph G is kcritical if X(G) = k but every proper subgraph has chromatic number less than k. As kcritical graphs can be viewed as minimal examples of graphs with chromatic number k, it is natural to ask how small such a graph can be. Let fk(n) denote the minimum number of edges in a kcritical graph on n vertices. The Ore construction, used to build larger kcritical graphs, implies that: fk(n + k  1) ≤ fk(n) + (k  1) [k/2  1/(k1)]. A recent paper by Kostochka and Yancey provides a lower bound for fk(n) which implies that the asymptotic density Φk := limn→∞ fk(n)/n = [k/2  1/(k1)] In this work, we use the method of discharging to prove a lower bound on the number of edges which includes structural information about the graph. This lower bound shows that the asymptotic density of a kcritical graph can be increased by ε > 0 by restricting to (Kk2)free kcritical graphs. We also prove that the graphs constructible from the Ore construction and Kk, called kOre graphs, are precisely the graphs which attain Kostochka and Yancey's bound. Moreover, we also provide results regarding subgraphs which must exist in kOre graphs. For the discharging argument, carried out in two stages, we also prove results regarding the density of nearlybipartite subgraphs in kcritical graphs. In the nal chapter we examine the minimal set of subgraphs, called kcritical structures, which one needs to forbid to obtain an ε increase in asymptotic density. This lays the groundwork for future research into asymptotic density in kcritical graphs.
Table of Contents
1 Introduction and history...1
1.1 Graph coloring...1
1.2 kcritical graphs...3
1.3 History of fk(n)...4
1.4 Results...6
2 Graph denitions and preliminaries...12
2.1 Denitions...12
2.2 Almostbipartite subgraphs in a kcritical graph...13
2.3 Further edge bound on kcritical graphs...18
3 Ore compositions and kOre graphs...19
3.1 Ore composition and potential function...20
3.2 Results on kOre graphs...23
3.3 Diamonds and emeralds...25
4 Potential and critical extensions...28
4.1 Potential...28
4.2 Critical extensions...29
4.3 Collapsible sets and edgeadditions...32
4.4 Generalization to icollapsible and (i + 1)edgeadditions...38
5 Cloning...48
5.1 Clusters...48
5.2 Gadgets and Kk3 subgraphs...54
5.3 Bounds on degrees of neighbors of structurevertices...57
6 Discharging...61
6.1 Discharging: setup and rst stage...62
6.2 Second stage: averaging charge over the graph...66
7 Tcs(G), a modication of T(G)...71
7.1 kcritical structures...72
7.2 Preliminaries...74
7.3 Main result on kOre graphs...78
Bibliography...98
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Supplemental Files
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mydata.tex ()  20180828 12:51:54 0400 


chapter2.tex ()  20180828 12:52:03 0400 


discharging.tex ()  20180828 12:52:11 0400 


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IntroHistory.tex ()  20180828 12:52:59 0400 


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cloning.tex ()  20180828 12:53:14 0400 


thesis.bib ()  20180828 12:53:18 0400 


TG2.fig ()  20180828 12:53:21 0400 
