Extremal graph theory is a branch of combinatorics, itself an area of mathematics, that lies at the intersection of extremal combinatorics and graph theory. In essence, extremal graph theory studies how global properties of a graph influence local substructure.Results in extremal graph theory deal with quantitative connections between various graph properties, both global (such as the number of vertices and edges) and local (such as the existence of specific subgraphs), and problems in extremal graph theory can often be formulated as optimization problems: how big or small a parameter of a graph can be, given some constraints that the graph has to satisfy?A graph that is an optimal solution to such an optimization problem is called an extremal graph, and extremal graphs are important objects of study in extremal graph theory.
Extremal graph theory is closely related to fields such as Ramsey theory, spectral graph theory, computational complexity theory, and additive combinatorics, and frequently employs the probabilistic method.
Mantel's Theorem (1907) and Turán's Theorem (1941) were some of the first milestones in the study of extremal graph theory. In particular, Turán's theorem would later on become a motivation for the finding of results such as the Erdős–Stone theorem (1946). This result is surprising because it connects the chromatic number with the maximal number of edges in an
H
See main article: Graph coloring.
A proper (vertex) coloring of a graph
G
G
G
G
\chi(G)
Two simple lower bounds to the chromatic number of a graph
G
\omega(G)
|V(G)|/\alpha(G)
\alpha(G)
A greedy coloring gives the upper bound
\chi(G)\le\Delta(G)+1
\Delta(G)
G
G
\Delta(G)
G
G
In general, determining whether a given graph has a coloring with a prescribed number of colors is known to be NP-hard.
In addition to vertex coloring, other types of coloring are also studied, such as edge colorings. The chromatic index
\chi'(G)
G
G
\Delta(G)
\Delta(G)+1
See main article: Forbidden subgraph problem.
The forbidden subgraph problem is one of the central problems in extremal graph theory. Given a graph
G
\operatorname{ex}(n,G)
n
G
When
G=Kr
\operatorname{ex}(n,Kr)
G
\operatorname{ex}(n,G)
G
\operatorname{ex}(n,G)
G
G
See main article: Homomorphism density.
The homomorphism density
t(H,G)
H
G
H
G
H
G
The forbidden subgraph problem can be restated as maximizing the edge density of a graph with
G
t(H,G)
H
A major open problem relating homomorphism densities is Sidorenko's conjecture, which states a tight lower bound on the homomorphism density of a bipartite graph in a graph
G
G
See main article: Szemerédi regularity lemma.
Szemerédi's regularity lemma states that all graphs are 'regular' in the following sense: the vertex set of any given graph can be partitioned into a bounded number of parts such that the bipartite graph between most pairs of parts behave like random bipartite graphs.This partition gives a structural approximation to the original graph, which reveals information about the properties of the original graph.
The regularity lemma is a central result in extremal graph theory, and also has numerous applications in the adjacent fields of additive combinatorics and computational complexity theory. In addition to (Szemerédi) regularity, closely related notions of graph regularity such as strong regularity and Frieze-Kannan weak regularity have also been studied, as well as extensions of regularity to hypergraphs.
Applications of graph regularity often utilize forms of counting lemmas and removal lemmas. In simplest forms, the graph counting lemma uses regularity between pairs of parts in a regular partition to approximate the number of subgraphs, and the graph removal lemma states that given a graph with few copies of a given subgraph, we can remove a small number of edges to eliminate all copies of the subgraph.
Related fields
Techniques and methods
Theorems and conjectures (in addition to ones mentioned above)