Indirect searches for New Physics via flavour observables

TL;DR

This paper reviews how precision electroweak and flavour measurements serve as indirect probes for New Physics, especially in light of recent anomalies and the role of neutrino models and Standard Model extensions.

Contribution

It provides a comprehensive analysis of flavour physics implications for New Physics, focusing on neutrino models and Standard Model extensions addressing current experimental tensions.

Findings

Identification of deviations in flavour observables from Standard Model predictions

Analysis of models of massive neutrinos and their phenomenological implications

Assessment of Standard Model extensions in explaining anomalies in magnetic moments and B-meson decays

Abstract

Precision measures of electroweak and flavour observables, at both low and high energies, are highly complementary to direct searches for New Physics at high-energy colliders. Despite the discovery of the Higgs boson at the Large Hadron Collider, and of the overwhelming successes of the Standard Model, several observational and theoretical problems remain to be addressed. In addition to neutrino oscillation phenomena, the Standard Model fails to explain the baryon asymmetry of the Universe, and does not offer a viable dark matter candidate. In recent years, numerous deviations between the Standard Model prediction and experimental measurements have been identified; interestingly, most are closely connected to lepton flavours. In this thesis we have explored several aspects of flavour physics, focusing on the phenomenological implications of models of massive neutrinos, and of several Standard Model extensions capable of accommodating current tensions on anomalous magnetic moments of charged leptons and several $B$-meson decay observables.