Unitarity and the three flavour neutrino mixing matrix

Unitarity is a fundamental property of any theory required to ensure we work in a theoretically consistent framework. In comparison with the quark sector, experimental tests of unitarity for the 3x3 neutrino mixing matrix are considerably weaker. It must be remembered that the vast majority of our i...

Full description

Saved in:
Bibliographic Details
Published in:arXiv.org 2015-08
Main Authors: Parke, Stephen, Ross-Lonergan, Mark
Format: Article
Language:English
Subjects:
Neutrinos
Triangles
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Unitarity is a fundamental property of any theory required to ensure we work in a theoretically consistent framework. In comparison with the quark sector, experimental tests of unitarity for the 3x3 neutrino mixing matrix are considerably weaker. It must be remembered that the vast majority of our information on the neutrino mixing angles originates from \(\overline{\nu}_e\) and \(\nu_\mu\) disappearance experiments, with the assumption of unitarity being invoked to constrain the remaining elements. New physics can invalidate this assumption for the 3x3 subset and thus modify our precision measurements. We perform a reanalysis to see how global knowledge is altered when one refits oscillation results without assuming unitarity, and present \(3 \sigma\) ranges for allowed \(U_\text{PMNS}\) elements consistent with all observed phenomena. We calculate the bounds on the closure of the six neutrino unitarity triangles, with the closure of the \(\nu_e \nu_\mu\) triangle being constrained to be \(\leq\) 0.03, while the remaining triangles are significantly less constrained to be \(\leq\) 0.1 - 0.2. Similarly for the row and column normalization, we find their deviation from unity is constrained to be \(\leq\) 0.2 - 0.4, for four out of six such normalisations, while for the \(\nu_\mu\) and \(\nu_e\) row normalisation the deviations are constrained to be \(\leq\) 0.07, all at the \(3\sigma\) CL. We emphasise that there is significant room for new low energy physics, especially in the \(\nu_\tau\) sector which very few current experiments constrain directly.
ISSN:2331-8422
DOI:10.48550/arxiv.1508.05095