From Dark Sectors to the Axion-Neutrino Connection

TL;DR

This paper explores interconnected beyond Standard Model theories addressing neutrino masses, dark matter, and CP violation, proposing novel mechanisms and models with testable predictions for experiments and cosmology.

Contribution

It introduces new BSM frameworks linking dark sectors, neutrino masses, and axion physics, emphasizing their testability and phenomenological implications.

Findings

Dark linear seesaw links neutrino masses to dark matter candidates.

Spontaneous CP violation from a scalar singlet explains leptogenesis.

Unified axion models predict distinctive couplings and viable dark matter scenarios.

Abstract

The Standard Model (SM) of particle physics provides a successful description of fundamental particles and their interactions but fails to explain phenomena such as neutrino oscillations, dark matter (DM), and the baryon asymmetry of the Universe. These clear signs of BSM physics motivate extensions introducing new particles and symmetries. Theoretical questions like the flavor puzzle and the strong CP problem further guide BSM frameworks. This thesis explores BSM scenarios based on two guiding principles: constructing unified frameworks that address multiple open problems in (astro)particle physics and cosmology, and emphasizing their experimental testability through detailed phenomenological analyses. This approach uncovers deep connections between seemingly disconnected sectors, offering a more complete view of fundamental physics. We investigate dark sector models for the origin of neutrino masses, proposing a novel setup: dark linear seesaw, which radiatively links neutrino mass generation to DM candidates and predicts charged lepton flavor violation. In these scenarios, dark sector particles can constitute WIMP DM, testable via direct detection experiments. We study spontaneous CP violation induced by a complex scalar singlet, acting as a common origin of low- and high-energy CP violating effects relevant for leptogenesis. We also analyze a Nelson-Barr model that solves the strong CP problem, generates a realistic CKM matrix radiatively, and yields scalar WIMP DM. Additionally, we present unified axion frameworks in which a colored sector radiatively generates neutrino masses. These models predict distinctive axion couplings to photons and fermions and accommodate axion DM in both pre- and post-inflationary cosmologies. Finally, we explore minimal flavored Peccei-Quinn symmetries that link the flavor puzzle, neutrino masses and DM within a predictive and testable framework.