Elements of F-ast Proton Decay

TL;DR

This paper updates the theoretical predictions for proton decay in certain GUT models, showing that recent F-theory models with TeV-scale multiplets could produce observable proton decay signals in upcoming experiments.

Contribution

It provides an improved analysis of unification parameters, correcting previous errors, and demonstrates that F-theory derived GUT models may yield detectable proton decay within next-generation detector sensitivities.

Findings

F-ast proton decay predictions are close to current experimental limits.

TeV-scale vector multiplets can extend unification scales towards the Planck mass.

Next-generation detectors like DUSEL and Hyper-Kamiokande could observe these decay modes.

Abstract

Gauge coupling unification in the Minimal Supersymmetric Standard Model (MSSM) strongly suggests the existence of a Grand Unified Theory (GUT), which could be probed by the observation of proton decay. Proton lifetime in the p \to (e+|mu+) pi0 dimension six mode is proportional in the fourth power to the GUT mass scale, and inversely proportional in the fourth power to the GUT coupling. We provide an updated dictionary of solutions for the relevant unification parameters with generic beta-function coefficients, significantly upgrading the level of detail with which second order effects are treated, and correcting subtle published errors. F-lipped SU(5) with strict MSSM field content is known to survive existing null detection limits for proton decay approaching 10^34 years, and indeed, the lifetime predicted by prior studies can be so long that successful detection is not currently plausible. Recently studied classes of F-theory derived GUT models postulate additional vector-like multiplets at the TeV scale which modify the renormalization group to yield a substantial increase in the SU(3)_C X SU(2)_L unified coupling. We find the conjunction of these models with the F-resh analysis employed to be comparatively F-ast proton decay, only narrowly evading existing detection limits, and likely falling within the observable range of proposed next generation detectors such as DUSEL and Hyper-Kamiokande. The TeV-scale vector multiplets are themselves suitable for cross correlation by the Large Hadron Collider. Their presence moreover magnifies the gap between the dual mass scales of Flipped SU(5), allowing for an elongated second stage renormalization, pushing grand unification to the doorstep of the reduced Planck mass.