Right-handed neutrino dark matter in the classically conformal 
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 extended standard model

Oda, S.; Okada, Nobuchika; Takahashi, Daisuke

doi:10.1103/physrevd.96.095032

Cited by 27 publications

(17 citation statements)

References 107 publications

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“…Hence, it is very important to study models that can simultaneously explain neutrino mass as well as DM and their theoretical as well as phenomenological implications. The models with an extra U (1) gauge group can accommodate a DM candidate even in the minimal version (with type-I seesaw), by adding an additional Z 2 symmetry [26,27], where the third generation of the right handed neutrinos act as the DM candidate. Other versions of the U (1) B−L extension with scalar DM have been studied in [28][29][30][31].Also, there are various realizations of the grand unified theories (GUTs) that predict the existence of extra Z boson [32,33].…”

Section: Introductionmentioning

confidence: 99%

Constraining a general U(1)′ inverse seesaw model from vacuum stability, dark matter, and collider

et al. 2020

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We consider a class of gauged U (1) extensions of the Standard Model (SM), where the light neutrino masses are generated by an inverse seesaw mechanism. In addition to the three right handed neutrinos, we add three singlet fermions and demand an extra Z 2 symmetry under which, the third generations of both of the neutral fermions are odd, which in turn gives us a stable dark matter candidate. We express the U (1) charges of all the fermions in terms of the U(1) charges of the standard model Higgs and the new complex scalar. We study the bounds on the parameters of the model from vacuum stability, perturbative unitarity, dark matter relic density and direct detection constraints. We also obtain the collider constraints on the Z mass and the U (1) gauge coupling. Finally we compare all the bounds on the Z mass versus the U (1) gauge coupling plane.

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Section: Introductionmentioning

confidence: 99%

Constraining a general U(1)′ inverse seesaw model from vacuum stability, dark matter, and collider

et al. 2020

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“…The phenomenology of the Z ′ -portal RHN DM in the context of the minimal U(1) X model has been studied in Ref. [13] (see also [14]) to identify the allowed parameter region from the cosmological and collider phenomenology constraints. Furthermore, an extension of the U(1) X model to SU(5)×U(1) X grand unification has been proposed in Ref.…”

Section: Introductionmentioning

confidence: 99%

Natural Z′ -portal Majorana dark matter in alternative U(1) extended standard model

Okada

Raut

2019

Phys. Rev. D

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We consider a non-exotic gauged U(1) X extension of the Standard Model (SM), where the U(1) X charge of a SM field is given by a linear combination of its hypercharge and Baryonminus-Lepton (B − L) number. All the gauge and mixed gauge-gravitational anomalies are canceled in this model with the introduction of three right-handed neutrinos (RHNs). Unlike the conventional minimal U(1) X model, where a universal U(1) X charge of −1 is assigned to three RHNs, we consider an alternative charge assignment, namely, two RHNs (N 1,2 R ) have U(1) X charge −4 while one RHN (N R ) has a +5 charge. With a minimal extension of the Higgs sector, the three RHNs acquire their Majorana masses associated with U(1) X symmetry breaking. While N 1,2 R have Yukawa coupling with the SM lepton doublets and play an essential role for the "minimal seesaw" mechanism, N R is isolated from the SM particles due to its U(1) X charge and hence it is a natural candidate for the dark matter (DM) without invoking additional symmetries. In this model context, we investigate the Z ′ -portal RHN DM scenario, where the RHN DM communicates with the SM particles through the U(1) X gauge boson (Z ′ boson). We identify a narrow parameter space by combining the constraints from the observed DM relic abundance, the results of the search for a Z ′ boson resonance at the Large Hadron Collider Run-2, and the gauge coupling perturbativity up to the Planck/Grand Unification scale. A special choice of U(1) X charges for the SM fields allows us to extend the model to SU(5)×U(1) X grand unification. In this scenario, the model parameter space is more severely constrained, which will be explored at future high energy collider experiments.

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“…Scale-invariant extensions of the SM can also provide a DM candidate (for recent papers see e.g. [70][71][72][73][74][75][76][77][78][79][80]). Particle nature of the DM is another important puzzle in particle cosmology [81].…”

Section: Introductionmentioning

confidence: 99%

Gravitational waves from scale-invariant vector dark matter model: probing below the neutrino-floor

Mohamadnejad

2020

Eur. Phys. J. C

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We study the gravitational waves (GWs) spectrum produced during the electroweak phase transition in a scale-invariant extension of the Standard Model (SM), enlarged by a dark U (1)D gauge symmetry. This symmetry incorporates a vector dark matter (DM) candidate and a scalar field (scalon). Because of scale invariance, the model has only two independent parameters and for the parameter space constrained by DM relic density, strongly first-order electroweak phase transition can take place. In this model, for a narrow part of the parameter space, DM-nucleon cross section is below the neutrino-floor limit, and therefore, it cannot be probed by the future direct detection experiments. However, for a benchmark point form this narrow region, we show the amplitude and frequency of phase transition GW spectrum fall within the observational window of space-based GW detectors such as eLISA.

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Right-handed neutrino dark matter in the classically conformal U(1)′ extended standard model

Cited by 27 publications

References 107 publications

Constraining a general U(1)′ inverse seesaw model from vacuum stability, dark matter, and collider

Constraining a general U(1)′ inverse seesaw model from vacuum stability, dark matter, and collider

Natural Z′ -portal Majorana dark matter in alternative U(1) extended standard model

Gravitational waves from scale-invariant vector dark matter model: probing below the neutrino-floor

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