Erdős–Burr conjecture

In mathematics, the Erdős–Burr conjecture is a problem concerning the Ramsey number of sparse graphs. The conjecture is named after Paul Erdős and Stefan Burr, and is one of many conjectures named after Erdős; it states that the Ramsey number of graphs in any sparse family of graphs should grow linearly in the number of vertices of the graph.

In 2015, a proof of the conjecture was announced by Choongbum Lee.^[1]

Definitions

If G is an undirected graph, then the degeneracy of G is the minimum number p such that every subgraph of G contains a vertex of degree p or smaller. A graph with degeneracy p is called p-degenerate. Equivalently, a p-degenerate graph is a graph that can be reduced to the empty graph by repeatedly removing a vertex of degree p or smaller.

It follows from Ramsey's theorem that for any graph G there exists a least integer $r(G)$ , the Ramsey number of G, such that any complete graph on at least $r(G)$ vertices whose edges are coloured red or blue contains a monochromatic copy of G. For instance, the Ramsey number of a triangle is 6: no matter how the edges of a complete graph on six vertices are colored red or blue, there is always either a red triangle or a blue triangle.

The conjecture

In 1973, Paul Erdős and Stefan Burr made the following conjecture:

For every integer p there exists a constant c_p so that any p-degenerate graph G on n vertices has Ramsey number at most c_p n.

That is, if an n-vertex graph G is p-degenerate, then a monochromatic copy of G should exist in every two-edge-colored complete graph on c_p n vertices.

Known results

Although a proof of full conjecture has not been published, it has been settled in some special cases. It was proven for bounded-degree graphs by Chvátal et al. (1983); their proof led to a very high value of c_p, and improvements to this constant were made by Eaton (1998) and Graham, Rödl & Ruciński (2000). More generally, the conjecture is known to be true for p-arrangeable graphs, which includes graphs with bounded maximum degree, planar graphs and graphs that do not contain a subdivision of K_p.^[2] It is also known for subdivided graphs, graphs in which no two adjacent vertices have degree greater than two.^[3]

For arbitrary graphs, the Ramsey number is known to be bounded by a function that grows only slightly superlinearly. Specifically, Fox & Sudakov (2009) showed that there exists a constant c_p such that, for any p-degenerate n-vertex graph G,

r(G) \leq 2^{c_p \sqrt{\log n}} n.

Notes

References

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Graham, Ronald; Rödl, Vojtěch; Ruciński, Andrzej (2000), "On graphs with linear Ramsey numbers", Journal of Graph Theory, 35 (3): 176–192, doi:10.1002/1097-0118(200011)35:3<176::AID-JGT3>3.0.CO;2-C, MR 1788033 .
Graham, Ronald; Rödl, Vojtěch; Ruciński, Andrzej (2001), "On bipartite graphs with linear Ramsey numbers", Paul Erdős and his mathematics (Budapest, 1999), Combinatorica, 21 (2): 199–209, doi:10.1007/s004930100018, MR 1832445
Kalai, Gil (May 22, 2015), "Choongbum Lee proved the Burr-Erdős conjecture", Combinatorics and more, retrieved 2015-05-22
Lee, Choongbum (2015), Ramsey numbers of degenerate graphs, arXiv:1505.04773
Li, Yusheng; Rousseau, Cecil C.; Soltés, Ľubomír (1997), "Ramsey linear families and generalized subdivided graphs", Discrete Mathematics, 170 (1–3): 269–275, doi:10.1016/S0012-365X(96)00311-1, MR 1452956 .
Rödl, Vojtěch; Thomas, Robin (1991), "Arrangeability and clique subdivisions", in Graham, Ronald; Nešetřil, Jaroslav, The Mathematics of Paul Erdős, II (PDF), Springer-Verlag, pp. 236–239, MR 1425217 .

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