A model explaining the new CDF II W boson mass linking to muon g-2 and dark matter

A model explaining the new CDF II W boson mass linking to muon g-2 and dark matter

We propose a model to explain the W boson mass anomaly reported by CDFII collaboration that would suggest new physics (NP). We introduce exotic fermions; one isospin doublet vector-like lepton, one isospin singlet singly-charged vector-like lepton, and an isospin doublet inert scalar. The proposed m...

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Veröffentlicht in:European physical journal plus 2023-04, Vol.138 (4), p.365, Article 365
Hauptverfasser: Nagao, Keiko I., Nomura, Takaaki, Okada, Hiroshi
Format: Artikel
Sprache:eng
Schlagworte:
Applied and Technical Physics
Atomic
Bosons
Charged particles
Collaboration
Complex Systems
Condensed Matter Physics
Dark matter
Fermions
Leptons
Magnetic moments
Mathematical and Computational Physics
Mathematical models
Molecular
Muons
Numerical analysis
Optical and Plasma Physics
Parameters
Physics
Physics and Astronomy
Quarks
Regular Article
Scalars
Symmetry
Theoretical
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container_title European physical journal plus
container_volume 138
creator Nagao, Keiko I.
Nomura, Takaaki
Okada, Hiroshi
description We propose a model to explain the W boson mass anomaly reported by CDFII collaboration that would suggest new physics (NP). We introduce exotic fermions; one isospin doublet vector-like lepton, one isospin singlet singly-charged vector-like lepton, and an isospin doublet inert scalar. The proposed model provides sizable muon anomalous magnetic moment (muon g - 2 ) due to no chiral suppression and nonzero mass difference between the real and imaginary parts of neutral inert scalar bosons. The inert scalar mass squared difference and vector-like exotic leptons ( L', E' in the main text) affect oblique parameters. Especially, T -parameter shift from zero explains the W boson mass anomaly. We search for the allowed parameter region to explain both muon g - 2 and W boson mass anomaly at the same time. We also discuss a dark matter (DM) candidate assuming the real part of the inert scalar field to be the one. We find that lighter DM mass is favored to be consistent with experimental constraints.
doi_str_mv 10.1140/epjp/s13360-023-03992-5
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subjects Applied and Technical Physics
Atomic
Bosons
Charged particles
Collaboration
Complex Systems
Condensed Matter Physics
Dark matter
Fermions
Leptons
Magnetic moments
Mathematical and Computational Physics
Mathematical models
Molecular
Muons
Numerical analysis
Optical and Plasma Physics
Parameters
Physics
Physics and Astronomy
Quarks
Regular Article
Scalars
Symmetry
Theoretical
title A model explaining the new CDF II W boson mass linking to muon g-2 and dark matter
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