Colouring normal quadrangulations of projective spaces

Abstract

Youngs proved that every non-bipartite quadrangulation of the projective plane RP2 is 4-chromatic. Kaiser and Stehl\'k [J. Combin. Theory Ser. B 113 (2015), 1-17] generalised the notion of a quadrangulation to higher dimensions and extended Youngs' theorem by proving that every non-bipartite quadrangulation of the d-dimensional projective space RPd with d ≥ 2 has chromatic number at least d+2. On the other hand, Hachimori et al. [European. J. Combin. 125 (2025), 104089] defined another kind of high-dimensional quadrangulation, called a normal quadrangulation. They proved that if a non-bipartite normal quadrangulation G of RPd with any d ≥ 2 satisfies a certain geometric condition, then G is 4-chromatic, and asked whether the geometric condition can be removed from the result. In this paper, we give a negative solution to their problem for the case d=3, proving that there exist 3-dimensional normal quadrangulations of RP3 whose chromatic number is arbitrarily large. Moreover, we prove that no normal quadrangulation of RPd with any d ≥ 2 has chromatic number 3.

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