# Right-handed neutrino dark matter in the classically conformal U(1)'   extended Standard Model

**Authors:** Satsuki Oda, Nobuchika Okada, and Dai-suke Takahashi

arXiv: 1704.05023 · 2017-12-06

## TL;DR

This paper explores right-handed neutrino dark matter within a classically conformal U(1)' extended Standard Model, analyzing constraints from vacuum stability, collider bounds, and relic density, and finds viable parameter space with suppressed direct detection signals.

## Contribution

It introduces a Z2-parity stabilized right-handed neutrino dark matter candidate in a conformal U(1)' model, constrained by multiple experimental and theoretical considerations.

## Key findings

- Allowed Z' mass is above ~3.5 TeV.
- RHN DM annihilates mainly via Z' portal.
- Direct detection cross section is below current bounds.

## Abstract

We consider the dark matter (DM) scenario in the context of the classically conformal U(1)' extended standard model (SM), with three right-handed neutrinos (RHNs) and the U(1)' Higgs field. The model is free from all the U(1)' gauge and gravitational anomalies in the presence of the three RHNs. We introduce a $Z_2$-parity in the model, under which an odd-parity is assigned to one RHN, while all the other particles is assigned to be $Z_2$-even, and hence the $Z_2$-odd RHN serves as a DM candidate. In this model, the U(1)' gauge symmetry is radiatively broken through the Coleman-Weinberg mechanism, by which the electroweak symmetry breaking is triggered. There are three free parameters in our model, the U(1)' charge of the SM Higgs doublet ($x_H$), the new U(1)' gauge coupling ($g_X$), and the U(1)' gauge boson ($Z'$) mass ($m_{Z'}$), which are severely constrained in order to solve the electroweak vacuum instability problem, and satisfy the LHC Run-2 bounds from the search for $Z'$ boson resonance. In addition to these constraints, we investigate the RHN DM physics. Because of the nature of classical conformality, we find that a RHN DM pair mainly annihilates into the SM particles through the $Z'$ boson exchange. This is the so-called $Z'$-portal DM scenario. Combining the electroweak vacuum stability condition, the LHC Run-2 bounds, and the cosmological constraint from the observed DM relic density, we find that all constrains complementarily work to narrow down the allowed parameter regions, and, especially, exclude $m_{Z'} \lesssim 3.5$ TeV. For the obtained allowed regions, we calculate the spin-independent cross section of the RHN DM with nucleons. We find that the resultant cross section well below the current experimental upper bounds.

## Full text

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## Figures

20 figures with captions in the complete paper: https://tomesphere.com/paper/1704.05023/full.md

## References

119 references — full list in the complete paper: https://tomesphere.com/paper/1704.05023/full.md

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Source: https://tomesphere.com/paper/1704.05023