The fractional chromatic number of the plane is at least 4

Abstract

We prove that the fractional chromatic number f( R2) of the unit distance graph of the Euclidean plane is greater than or equal to 4. Interestingly, however, we cannot present a finite subgraph G of the plane such that f(G) 4. Instead, we utilize the concept of the geometric fractional chromatic number gf(G), which was introduced recently in connection with density bounds for 1-avoiding sets. First, as G ranges over finite subgraphs of the plane, we establish that the supremum of f(G) is the same as that of gf(G). The proof exploits the amenability of the group of Euclidean transformations in dimension 2 and, as such, we do not know whether the analogous statement holds in higher dimensions. We then present a specific planar unit distance graph G on 27 vertices such that gf(G)=4, and conclude f( R2) 4 as a corollary. As another main result we show that the finitary fractional chromatic number and the Hall ratio of the plane are equal. As a consequence, we conclude that there exist finite unit distance graphs with independence ratio 14+, while we conjecture that the value 14 cannot be reached.

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