Combinatorial characterization of Schur ultrafilters on countable commutative groups, plus construction of a free non-infinitary Schur ultrafilter on Z and existence of a free Schur P-point on Z under CH.
Schur Number Five
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abstract
We present the solution of a century-old problem known as Schur Number Five: What is the largest (natural) number $n$ such that there exists a five-coloring of the positive numbers up to $n$ without a monochromatic solution of the equation $a + b = c$? We obtained the solution, $n = 160$, by encoding the problem into propositional logic and applying massively parallel satisfiability solving techniques on the resulting formula. We constructed and validated a proof of the solution to increase trust in the correctness of the multi-CPU-year computations. The proof is two petabytes in size and was certified using a formally verified proof checker, demonstrating that any result by satisfiability solvers---no matter how large---can now be validated using highly trustworthy systems.
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2026 1verdicts
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Combinatorics of Schur ultrafilters
Combinatorial characterization of Schur ultrafilters on countable commutative groups, plus construction of a free non-infinitary Schur ultrafilter on Z and existence of a free Schur P-point on Z under CH.