Probing Supersymmetric Leptogenesis with mu --> e gamma

TL;DR

This paper establishes an upper bound on the smallest neutrino Yukawa coupling and the lightest right-handed neutrino mass in supersymmetric models, linking these bounds to the non-observation of mu --> e gamma decay and implications for leptogenesis.

Contribution

It demonstrates a novel connection between rare lepton decay limits and constraints on neutrino Yukawa couplings and right-handed neutrino masses in supersymmetric models.

Findings

Upper bound on the smallest neutrino Yukawa eigenvalue.

Upper bound on the lightest right-handed neutrino mass (~5x10^12 GeV).

Potential to rule out minimal leptogenesis with increased experimental sensitivity.

Abstract

Extending the Minimal Supersymmetric Standard Model with three right-handed neutrino superfields is one of the best motivated scenarios for physics beyond the Standard Model. However, very little is known from observations about the high energy parameters of this model. In this paper we show, under the plausible assumptions that the neutrino Yukawa eigenvalues are hierarchical and the absence of cancellations, that there exists an upper bound on the smallest Yukawa eigenvalue stemming from the non-observation of the rare lepton decay mu --> e gamma. Furthermore, we show that this bound implies an upper bound on the lightest right-handed neutrino mass of approximately 5x10^12 GeV for typical supersymmetric parameters. We also discuss the implications of this upper bound for the minimal leptogenesis scenario based on the decay of the lightest right-handed neutrino and we argue that an improvement of sensitivity of six orders of magnitude to the process mu --> e gamma could rule out this mechanism as the origin of the observed baryon asymmetry, unless the neutrino parameters take very specific values.