Scale Invariant Instantons and the Complete Lifetime of the Standard Model

TL;DR

This paper provides a complete, gauge-invariant calculation of the Standard Model's vacuum lifetime, resolving previous divergences and uncertainties, and estimates the universe's stability with high confidence.

Contribution

It introduces a method to sum higher-loop corrections in scale-invariant theories and produces the first exact solutions for functional determinants around the bounce.

Findings

Universe lifetime estimated at 10^139 years

Universe is stable with 95% confidence for over 10^58 years

Phase diagrams with uncertainty bands for stability regions

Abstract

In a classically scale-invariant quantum field theory, tunneling rates are infrared divergent due to the existence of instantons of any size. While one expects such divergences to be resolved by quantum effects, it has been unclear how higher-loop corrections can resolve a problem appearing already at one loop. With a careful power counting, we uncover a series of loop contributions that dominate over the one-loop result and sum all the necessary terms. We also clarify previously incomplete treatments of related issues pertaining to global symmetries, gauge fixing and finite mass effects. In addition, we produce exact closed-form solutions for the functional determinants over scalars, fermions and vector bosons around the scale-invariant bounce, demonstrating manifest gauge invariance in the vector case. With these problems solved, we produce the first complete calculation of the lifetime of our universe: 10^139 years. With 95% confidence, we expect our universe to last more than 10^58 years. The uncertainty is part experimental uncertainty on the top quark mass and on ${\alpha}s$ and part theory uncertainty from electroweak threshold corrections. Using our complete result, we provide phase diagrams in the $mt/mh$ and the $mt/{\alpha}s$ planes, with uncertainty bands. To rule out absolute stability to $3{\sigma}$ confidence, the uncertainty on the top quark pole mass would have to be pushed below 250 MeV or the uncertainty on ${\alpha}s(mZ)$ pushed below 0.00025.