Strong CP Problem Series-Paper 3 We establish that the strong CP parameter θQCD is constrained to zero on Pin⁺ manifolds through a two-stage argument: (i) a topological constraint from the Pin⁺ structure that restricts θ to 0, π, and (ii) a physical constraint that excludes θ = π due to its cosmological consequences. Specifically, the time-reversal symmetry inherent in Pin⁺ manifolds forces θ ∈ 0, π, while θ = π triggers spontaneous CP violation and domain wall formation that is cosmologically unacceptable. This resolves the tension identified by Witten (2015), who showed that θ = π is topologically well-defined on Pin⁺ manifolds as a topological insulator state—our analysis confirms this topological legitimacy while demonstrating that θ = π is excluded not by topology alone but by physical cosmological constraints. We note that θQCD = 0 constrains only the bare angle; the physical parameter θ̄ = θQCD + arg det Mq additionally requires arg det Mq = 0, which is a separate question beyond the scope of this work. We further establish that this two-stage argument is the unique consistent resolution within the Pin⁺ bordism framework, where the Pin⁺ bordism group Ω₄Pin⁺ = Z₁₆ provides the quantitative topological foundation. The result θ = 0 is thus not a direct consequence of Pin⁺ structure alone, but of Pin⁺ structure combined with the physical requirement of cosmological viability.
Fangyuan Hao (Tue,) studied this question.