Neutrinos in Cosmology after Planck: What are their masses, properties, and relationship with the Hubble tension?
APA
Escudero, M. (2020). Neutrinos in Cosmology after Planck: What are their masses, properties, and relationship with the Hubble tension?. Perimeter Institute. https://pirsa.org/20060051
MLA
Escudero, Miguel. Neutrinos in Cosmology after Planck: What are their masses, properties, and relationship with the Hubble tension?. Perimeter Institute, Jun. 23, 2020, https://pirsa.org/20060051
BibTex
@misc{ pirsa_PIRSA:20060051, doi = {10.48660/20060051}, url = {https://pirsa.org/20060051}, author = {Escudero, Miguel}, keywords = {Particle Physics}, language = {en}, title = {Neutrinos in Cosmology after Planck: What are their masses, properties, and relationship with the Hubble tension?}, publisher = {Perimeter Institute}, year = {2020}, month = {jun}, note = {PIRSA:20060051 see, \url{https://pirsa.org}} }
Neutrinos are a key (although implicit) ingredient of the standard cosmological model, LambdaCDM. Firstly, neutrinos directly participate in neutron freeze out during BBN, and secondly, they represent 40% of the energy density of the Universe after electron positron annihilation up to almost matter radiation equality. The latter fact makes neutrinos a necessary element to understand CMB observations.
In this talk, I will review the cosmological implications of neutrinos. I will explain how current cosmological observations can be used to constrain their masses, their abundances, and their properties -- such as their interaction rate with other species. In particular, I will highlight that the typically very stringent constraint on their masses can be substantially relaxed if neutrinos decay on cosmological timescales. I will illustrate the implications of neutrino decays in cosmology with a few well-motivated neutrino mass models in which neutrinos can decay. I will then show that Planck CMB observations are a powerful tool to constraint neutrino interactions with neutrinophilic bosons. In particular, I will demonstrate that Planck legacy constraints neutrinophilic bosons with couplings as small as 10^{-13} with neutrinos for boson masses in the 0.1 eV < m < 300 eV range. I will finish by reviewing the role neutrinos can play with regards to the outstanding Hubble tension. I will show that pseudogoldstone bosons (majorons) interacting with neutrinos right before recombination represent a well motivated possibility to ameliorate (and potentially solve) the Hubble tension.