Neutrino masses and Hubble tension via a Majoron in MFV-Reference-Cited by-同舟云学术

Neutrino masses and Hubble tension via a Majoron in MFV

Published:2021-01 Issue:1 Volume:81 Page:
ISSN:1434-6044
Container-title:The European Physical Journal C
language:en
Short-container-title:Eur. Phys. J. C

Author:

Arias-Aragón Fernando,Fernández-Martínez Enrique,González-López Manuel^ORCID,Merlo Luca

Abstract

AbstractThe recent tension between local and early measurements of the Hubble constant can be explained in a particle physics context. A mechanism is presented where this tension is alleviated due to the presence of a Majoron, arising from the spontaneous breaking of Lepton Number. The lightness of the active neutrinos is consistently explained. Moreover, this mechanism is shown to be embeddable in the minimal (Lepton) flavour violating context, providing a correct description of fermion masses and mixings, and protecting the flavour sector from large deviations from the Standard Model predictions. A QCD axion is also present to solve the Strong CP problem. The Lepton Number and the Peccei–Quinn symmetries naturally arise in the minimal (Lepton) flavour violating setup and their spontaneous breaking is due to the presence of two extra scalar singlets. The Majoron phenomenology is also studied in detail. Decays of the heavy neutrinos and the invisible Higgs decay provide the strongest constraints in the model parameter space.

Funder

Centro de excelencia Severo Ochoa Program

Agencia Estatal de Investigación, Spanish MINECO

Publisher

Springer Science and Business Media LLC

Subject

Physics and Astronomy (miscellaneous),Engineering (miscellaneous)

Link

http://link.springer.com/content/pdf/10.1140/epjc/s10052-020-08825-8.pdf

Reference134 articles.

1. L. Verde, T. Treu, A. Riess, Tensions Between the Early and the Late Universe (2019). arXiv:1907.10625

2. K.C. Wong et al., H0LiCOW XIII. A 2.4% measurement of $$H_{0}$$ from lensed quasars: $$5.3\sigma $$ tension between early and late-Universe probes (2019). arXiv:1907.04869

3. Planck Collaboration, N. Aghanim et al., Planck 2018 Results. VI. Cosmological Parameters (2018). arXiv:1807.06209

4. A.G. Riess, S. Casertano, W. Yuan, L.M. Macri, D. Scolnic, Large magellanic cloud cepheid standards provide a 1% foundation for the determination of the hubble constant and stronger evidence for physics beyond $$\Lambda $$CDM. Astrophys. J. 876(1), 85 (2019). arXiv:1903.07603

5. M. Archidiacono, S. Gariazzo, C. Giunti, S. Hannestad, R. Hansen, M. Laveder, T. Tram, Pseudoscalar–Sterile neutrino interactions: reconciling the cosmos with neutrino oscillations. JCAP 08, 067 (2016). arXiv:1606.07673

Cited by 24 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Self-interacting neutrinos in light of large-scale structure data;Physical Review D;2024-05-16

2. The minimal massive Majoron Seesaw Model;Journal of High Energy Physics;2024-03-15

3. Limits on ALP-neutrino couplings from loop-level processes;Physical Review D;2024-03-13

4. Atacama Cosmology Telescope: The persistence of neutrino self-interaction in cosmological measurements;Physical Review D;2024-02-01

5. On the Dark Radiation Role in the Hubble Constant Tension;Springer Series in Astrophysics and Cosmology;2024