Stable fermion mass matrices and the charged lepton contribution to neutrino mixing

TL;DR

This paper investigates hierarchical fermion mass matrices, focusing on charged lepton contributions to neutrino mixing, showing they can explain observed mixing angles without fine-tuning and analyzing specific textures consistent with current data.

Contribution

It demonstrates that charged lepton mass matrices can fully account for lepton mixing angles and provides plausible textures consistent with experimental observations.

Findings

Charged lepton sector can explain all lepton mixing angles.

A non-zero 31 entry in the charged lepton mass matrix is supported by data.

Inverted order of rotations can be achieved without fine-tuning.

Abstract

We study the general properties of hierarchical fermion mass matrices in which the small eigenvalues are stable with respect to perturbations of the matrix entries and we consider specific applications to the charged lepton contribution to neutrino mixing. In particular, we show that the latter can account for the whole lepton mixing. In this case a value of $\sin \theta_{13} \gtrsim m_e/m_\mu \sin\theta_{23} \approx 0.03$, as observed, can be obtained without the need of any fine-tuning, and present data allow to determine the last row of the charged lepton mass matrix with good accuracy. We also consider the case in which the neutrino sector only provides a maximal 12 rotation and show that i) present data provide a $2\sigma$ evidence for a non-vanishing $31$ entry of the charged lepton mass matrix and ii) a plausible texture for the latter can account at the same time for the atmospheric mixing angle, the $\theta_{13}$ angle, and the deviation of the $\theta_{12}$ angle from $\pi/2$ without fine-tuning or tension with data. Finally, we show that the so-called "inverted order" of the 12 and 23 rotations in the charged lepton sector can be obtained without fine-tuning, up to corrections of order $m_e/m_\mu$.