Cosmology in Mirror Twin Higgs and neutrino masses

A bstract We explore a simple solution to the cosmological challenges of the original Mirror Twin Higgs (MTH) model that leads to interesting implications for experiment. We consider theories in which both the standard model and mirror neutrinos acquire masses through the familiar seesaw mechanism,...

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Bibliographic Details
Published in:The journal of high energy physics 2017-07, Vol.2017 (7), p.1-26, Article 23
Main Authors: Chacko, Zackaria, Craig, Nathaniel, Fox, Patrick J., Harnik, Roni
Format: Article
Language:English
Subjects:
Astronomical models
Beyond Standard Model
Big Bang theory
Classical and Quantum Gravitation
Cosmic microwave background
Cosmology
Cosmology of Theories beyond the SM
Decay
Elementary Particles
Flux density
High energy physics
Large scale structure of the universe
Neutrinos
Physics
Physics and Astronomy
PHYSICS OF ELEMENTARY PARTICLES AND FIELDS
Quantum Field Theories
Quantum Field Theory
Quantum Physics
Regular Article - Theoretical Physics
Relativity Theory
Scale (ratio)
Standard model (particle physics)
String Theory
Universe
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Summary:A bstract We explore a simple solution to the cosmological challenges of the original Mirror Twin Higgs (MTH) model that leads to interesting implications for experiment. We consider theories in which both the standard model and mirror neutrinos acquire masses through the familiar seesaw mechanism, but with a low right-handed neutrino mass scale of order a few GeV. In these ν MTH models, the right-handed neutrinos leave the thermal bath while still relativistic. As the universe expands, these particles eventually become nonrelativistic, and come to dominate the energy density of the universe before decaying. Decays to standard model states are preferred, with the result that the visible sector is left at a higher temperature than the twin sector. Consequently the contribution of the twin sector to the radiation density in the early universe is suppressed, allowing the current bounds on this scenario to be satisfied. However, the energy density in twin radiation remains large enough to be discovered in future cosmic microwave background experiments. In addition, the twin neutrinos are significantly heavier than their standard model counterparts, resulting in a sizable contribution to the overall mass density in neutrinos that can be detected in upcoming experiments designed to probe the large scale structure of the universe.
ISSN:1029-8479
1029-8479
DOI:10.1007/JHEP07(2017)023