No Countable Basis for Borel Directed Graphs of Dichromatic Number at Least Three

Abstract

I prove that the Borel directed graphs whose vertex set admits a partition into two Borel acyclic sets form a 12-complete set; equivalently, that deciding whether a Borel directed graph has Borel dichromatic number at least~3 is a 12-complete problem. It follows that no countable family of Borel directed graphs can serve as a basis for this class under Borel homomorphism and, more generally, that any basis must be at least as complex as~12. The proof lifts the classical NP-completeness reduction of Bokal, Fijavz, Juvan, Kayll, and Mohar to the Borel setting, using the coding framework of Thornton. Combined with a straightforward reduction from undirected to directed coloring problems, this completes the picture for finite Borel chromatic and dichromatic thresholds: for every finite k, the set of Borel (directed) graphs admitting a Borel k-(di)coloring is 12-complete, and in particular admits no countable basis. This contrasts with the uncountable threshold, where a single-element basis exists for Borel chromatic number (Kechris--Solecki--Todorcevi\'c) and a continuum-size basis exists for Borel dichromatic number (Raghavan--Xiao).