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Low scale U(1)X gauge symmetry as an origin of dark matter, neutrino mass and flavour anomalies

Debasish Borah, Lopamudra Mukherjee, Soumitra Nandi

2020Journal of High Energy Physics27 citationsDOIOpen Access PDF

Abstract

A bstract We study a generic leptophilic U(1) X extension of the standard model with a light gauge boson. The U(1) X charge assignments for the leptons are guided by lepton universality violating (LUV) observables in semileptonic b → sℓℓ decays, muon anomalous magnetic moment and the origin of leptonic masses and mixing. Anomaly cancellation conditions require the addition of new chiral fermions in the model, one of which acts as a dark matter (DM) candidate when it is stabilised by an additional $$ {\mathcal{Z}}_2 $$ <mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"> <mml:msub> <mml:mi>Z</mml:mi> <mml:mn>2</mml:mn> </mml:msub> </mml:math> symmetry. From our analysis, we show two different possible models with similar particle content that lead to quite contrasting neutrino mass origin and other phenomenology. The proposed models also have the potential to address the anomalous results in b → cℓν ℓ decays like R ( D ) , R ( D ∗ ), electron anomalous magnetic moment and the very recent KOTO anomaly in the kaon sector. We also discuss different possible collider signatures of our models which can be tested in future.

Topics & Concepts

PhysicsParticle physicsAnomalous magnetic dipole momentNeutrinoLeptonMuonAnomaly (physics)Dark matterPhysics beyond the Standard ModelGauge symmetryStandard Model (mathematical formulation)FermionGauge bosonGrand Unified TheoryObservableNeutrino oscillationNuclear physicsMass generationHidden sectorUniversality (dynamical systems)Lepton numberU-1Charge (physics)Gauge anomalySymmetry breakingSolar neutrinoColliderParticle physics theoretical and experimental studiesComputational Physics and Python ApplicationsDark Matter and Cosmic Phenomena