Chromatic number of spacetime

Abstract

We observe that an old theorem of Graham implies that for any positive integer s, there exists some positive integer T(s) such that every s-colouring of Z2 contains a monochromatic pair of points (x,y),(x',y') with (x-x')2 - (y-y')2 = (T(s))2. By scaling, this implies that every finite colouring of Q2 contains a monochromatic pair of points (x,y),(x',y') with (x-x')2 - (y-y')2 = 1, which answers in a strong sense a problem of Kosheleva and Kreinovich on a pseudo-Euclidean analogue of the Hadwiger-Nelson problem. The proof of Graham's theorem relies on repeated applications of van der Waerden's theorem, and so the resulting function T(s) grows extremely quickly. We give an alternative proof in the weaker setting of having a second spacial dimension that results in a significantly improved bound. To be more precise, we prove that for every positive integer s with r 2 4, every s-colouring of Z3 contains a monochromatic pair of points (x,y,z),(x',y',z') such that (x-x')2 + (y-y')2 - (z-z')2 = (5(s-2)/4(8· 5(s-2)/2)!)2. In fact, we prove a stronger density version. The density version in Z2 remains open.