Heavy Quarkonia in a Contact Interaction and an Algebraic Model: Mass Spectrum, Decay Constants, Charge Radii and Elastic and Transition Form Factors

For the flavor-singlet heavy quark system of bottomonia, we compute the masses of the ground state mesons in four different channels, namely, pseudo-scalar ( η b ( 1 S ) ), vector ( Υ ( 1 S ) ), scalar ( χ b 0 ( 1 P ) ) and axial vector ( χ b 1 ( 1 P ) ). We also calculate the weak decay constants o...

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Bibliographic Details
Published in:Few-body systems 2018-11, Vol.59 (6), p.1-16, Article 133
Main Authors: Raya, K., Bedolla, Marco A., Cobos-Martínez, J. J., Bashir, A.
Format: Article
Language:English
Subjects:
Algebra
Atomic
Channels
Constants
Decay
Form factors
Hadrons
Heavy Ions
Mathematical models
Mesons
Molecular
Momentum transfer
Nuclear Physics
Optical and Plasma Physics
Particle and Nuclear Physics
Photons
Physics
Physics and Astronomy
Quantum chromodynamics
Vector mesons
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Summary:For the flavor-singlet heavy quark system of bottomonia, we compute the masses of the ground state mesons in four different channels, namely, pseudo-scalar ( η b ( 1 S ) ), vector ( Υ ( 1 S ) ), scalar ( χ b 0 ( 1 P ) ) and axial vector ( χ b 1 ( 1 P ) ). We also calculate the weak decay constants of the η b ( 1 S ) and Υ ( 1 S ) as well as the charge radius of η b ( 1 S ) . It complements our previous study of the corresponding charmonia systems: η c ( 1 S ) , J / Ψ ( 1 S ) , χ c 0 ( 1 P ) ) and ( χ c 1 ( 1 P ) ). The unified formalism for this analysis is provided by a symmetry-preserving Schwinger–Dyson equations treatment of a vector  ×  vector contact interaction. Whenever a comparison is possible, our results are in fairly good agreement with experimental data, model calculations based upon Schwinger–Dyson and Bethe–Salpeter equations involving sophisticated interaction kernels as well as Lattice QCD. Within the same framework, we also report the elastic and transition form factors to two photons for the pseudo-scalar channels η c ( 1 S ) and η b ( 1 S ) in addition to the elastic form factors for the vector mesons J / Ψ and Υ for a wide range of photon momentum transfer squared ( Q 2 ). For η c ( 1 S ) and η b ( 1 S ) , we also provide predictions of an algebraic model which correlates remarkably well between the known infrared and ultraviolet limits of these form factors.
ISSN:0177-7963
1432-5411
DOI:10.1007/s00601-018-1455-y