The Proton Decay Test — Hyper-Kamiokande and the Cabibbo Doublet at MGUT = 10¹5. 5: MGUT = 10¹5. 5 → τ ~ 10³4-35 yr → Hyper-Kamiokande 2027-2037.

The Proton Decay Test — Hyper-Kamiokande and the Cabibbo Doublet at MGUT = 10¹5. 5: MGUT = 10¹5. 5 → τ ~ 10³4-35 yr → Hyper-Kamiokande 2027-2037. This paper is part of the HOWL research archive—a collection of physics papers exploring integer fraction derivations across multiple domains using exact arithmetic and automated comparison. Abstract The Cabibbo Doublet (3, 2, 1/6) produces a grand unification scale MGUT = 10¹5. 5 GeV from the one-loop running of the three SM gauge couplings with modified beta coefficients. In minimal SU (5), the proton lifetime for the dominant decay channel p → e⁺π⁰ scales as MGUT⁴, giving τ ~ 10³4-35 years for MGUT = 10¹5. 5. The current experimental bound from Super-Kamiokande is τ > 2. 4 × 10³4 years at 90% confidence level (Phys. Rev. D 102, 112011, 2020). The Cabibbo Doublet prediction sits at this boundary — the lower end of the range is already in tension with the data, while the upper end remains viable. Hyper-Kamiokande, the successor experiment with 8. 3 times the fiducial volume, is scheduled to begin operations in 2027 and will reach a sensitivity of approximately 10³5 years for p → e⁺π⁰ after 10 years of data collection and up to 10³5 years with 20 years. This covers the entire viable Cabibbo Doublet prediction range. The MSSM, by contrast, produces MGUT = 10¹7. 3 — nearly two orders of magnitude higher — yielding τ ~ 10³6-37 years, far beyond any planned experiment. Despite having nearly identical gap ratios (38/27 = 1. 407 vs 7/5 = 1. 400), the Cabibbo Doublet and the MSSM are separated by a factor of 10⁷ in proton lifetime because τ scales as the fourth power of MGUT. This makes proton decay the decisive discriminator. One experiment, one decade, one answer. Falsification Criteria All papers in this archive are subject to falsification through direct comparison to published experimental measurements. Each derived value is tested against independent data with explicit PASS/FAIL criteria. Any derived value that fails its comparison is documented and published alongside the successes. Research Context This archive documents an ongoing research program in integer fraction physics. The methodology is: derive values from gauge group integers using exact fraction arithmetic, compare to published measurements, and document all results including failures. The archive spans multiple physics domains connected through the soliton boundary framework described in the constituent papers. Package Contents manuscript. md: The complete derivation and supporting analysis. README. md: Navigation, dependencies, and citation (Registry: HOWL-PHYS-20-2026). Dependencies: HOWL-PHYS-1-2026, HOWL-PHYS-10-2026, HOWL-PHYS-11-2026, HOWL-PHYS-12-2026, HOWL-PHYS-13-2026, HOWL-PHYS-14-2026, HOWL-PHYS-15-2026, HOWL-PHYS-17-2026, HOWL-PHYS-18-2026, HOWL-PHYS-19-2026, HOWL-PHYS-2-2026, HOWL-PHYS-6-2026, HOWL-PHYS-7-2026, HOWL-PHYS-8-2026, HOWL-PHYS-9-2026 Motto: Derive. Compare. Publish. Status: Complete