(g − 2)e, μ and strongly interacting dark matter with collider implications

A bstract The quest for new physics beyond the Standard Model is boosted by the recently observed deviation in the anomalous magnetic moments of muon and electron from their respective theoretical prediction. In the present work, we have proposed a suitable extension of the minimal L μ − L τ model t...

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Bibliographic Details
Published in:The journal of high energy physics 2022-07, Vol.2022 (7), p.37-44, Article 37
Main Authors: Biswas, Anirban, Khan, Sarif
Format: Article
Language:English
Subjects:
Bosons
Classical and Quantum Gravitation
Cosmology of Theories BSM
Dark matter
Early Universe Particle Physics
Elementary Particles
Fermions
High energy physics
Leptons
Magnetic moments
Muons
Neutrinos
Particle Nature of Dark Matter
Physics
Physics and Astronomy
Quantum Field Theories
Quantum Field Theory
Quantum Physics
Regular Article - Theoretical Physics
Relativity Theory
Specific BSM Phenomenology
String Theory
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Summary:A bstract The quest for new physics beyond the Standard Model is boosted by the recently observed deviation in the anomalous magnetic moments of muon and electron from their respective theoretical prediction. In the present work, we have proposed a suitable extension of the minimal L μ − L τ model to address these two experimental results as the minimal model is unable to provide any realistic solution. In our model, a new Yukawa interaction involving first generation of leptons, a singlet vector like fermion ( χ ± ) and a scalar (either an SU(2) L doublet Φ 4 ′ or a complex singlet Φ 4 ′ ) provides the additional one loop contribution to a e only on top of the usual contribution coming from the L μ − L τ gauge boson ( Z μτ ) to both electron and muon. The judicious choice of L μ − L τ charges to these new fields results in a strongly interacting scalar dark matter in O (MeV) range after taking into account the bounds from relic density, unitarity and self interaction. The freeze-out dynamics of dark matter is greatly influenced by 3 → 2 scatterings while the kinetic equilibrium with the SM bath is ensured by 2 → 2 scatterings with neutrinos where Z μτ plays a pivotal role. The detection of dark matter is possible directly through scatterings with nuclei mediated by the SM Z bosons. Moreover, our proposed model can also be tested in the upcoming e + e − colliders by searching opposite sign di-electron and missing energy signal i.e. at the final state.
ISSN:1029-8479
1029-8479
DOI:10.1007/JHEP07(2022)037