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Cornell potential

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In particle physics, the Cornell potential is an effective method to account for the confinement of quarks in quantum chromodynamics (QCD). It was developed by Estia J. Eichten, Kurt Gottfried, Toichiro Kinoshita, John Kogut, Kenneth Lane and Tung-Mow Yan at Cornell University[1][2] in the 1970s to explain the masses of quarkonium states and account for the relation between the mass and angular momentum of the hadron (the so-called Regge trajectories). The potential has the form:[3]

where is the effective radius of the quarkonium state, is the QCD running coupling, is the QCD string tension and GeV is a constant. Initially, and were merely empirical parameters but with the development of QCD can now be calculated using perturbative QCD and lattice QCD, respectively.

Short distance potential

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The potential consists of two parts. The first one, dominate at short distances, typically for fm.[3] It arises from the one-gluon exchange between the quark and its anti-quark, and is known as the Coulombic part of the potential, since it has the same form as the well-known Coulombic potential induced by the electromagnetic force (where is the electromagnetic coupling constant).

The factor in QCD comes from the fact that quarks have different type of charges (colors) and is associated with any gluon emission from a quark. Specifically, this factor is called the color factor or Casimir factor and is , where is the number of color charges.

The value for depends on the radius of the studied hadron. Its value ranges from 0.19 to 0.4.[4] For precise determination of the short distance potential, the running of must be accounted for, resulting in a distant-dependent . Specifically, must be calculated in the so-called potential renormalization scheme (also denoted V-scheme) and, since quantum field theory calculations are usually done in momentum space, Fourier transformed to position space.[4]

Long distance potential

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The second term of the potential, , is the linear confinement term and fold-in the non-perturbative QCD effects that result in color confinement. is interpreted as the tension of the QCD string that forms when the gluonic field lines collapse into a flux tube. Its value is GeV.[4] controls the intercepts and slopes of the linear Regge trajectories.

Domains of application

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The Cornell potential applies best for the case of static quarks (or very heavy quarks with non-relativistic motion), although relativistic improvements to the potential using speed-dependent terms are available.[3] Likewise, the potential has been extended to include spin-dependent terms[3]

Calculation of the quark-quark potential

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A test of validity for approaches that seek to explain color confinement is that they must produce, in the limit that quark motions are non-relativistic, a potential that agrees with the Cornell potential.

A significant achievement of lattice QCD is to be able compute from first principles the static quark-antiquark potential, with results confirming the empirical Cornell Potential.[5]

Other approaches to the confinement problem also results in the Cornell potential, including the dual superconductor model, the Abelian Higgs model, and the center vortex models.[3][6]

More recently, calculations based on the AdS/CFT correspondence have reproduced the Cornell potential using the AdS/QCD correspondence[7][8] or light front holography.[9]

See also

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References

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  1. ^ Eichten, E.; Gottfried, K.; Kinoshita, T.; Kogut, J. B.; Lane, K. D.; Yan, T. M. (1975). "Spectrum of charmed quark-antiquark bound states". Phys. Rev. Lett. 34 (369): 369. Bibcode:1975PhRvL..34..369E. doi:10.1103/PhysRevLett.34.369.
  2. ^ Eichten, E.; Gottfried, K.; Kinoshita, T.; Lane, K. D.; Yan, T. M. (1978). "Charmonium: The model". Phys. Rev. D. 17 (3090): 3090. Bibcode:1978PhRvD..17.3090E. doi:10.1103/PhysRevD.17.3090.
  3. ^ a b c d e Brambilla, N.; Vairo, A. (1998). "Quark confinement and the hadron spectrum". Proceedings of the 13th Annual HUGS AT CEBAF. arXiv:hep-ph/9904330.
  4. ^ a b c Deur, A.; Brodsky, S. J.; de Teramond, G. F. (2016). "The QCD Running Coupling". Prog. Part. Nucl. Phys. 90 (1): 1–74. arXiv:1604.08082. Bibcode:2016PrPNP..90....1D. doi:10.1016/j.ppnp.2016.04.003. S2CID 118854278.
  5. ^ Bali, G. S. (2001). "QCD forces and heavy quark bound states". Phys. Rep. 343 (1): 1–136. arXiv:hep-ph/0001312. Bibcode:2001PhR...343....1B. doi:10.1016/S0370-1573(00)00079-X. S2CID 119050904.
  6. ^ Greensite, J. (2011). An introduction to the confinement problem. Lecture Notes in Physics. Vol. 821. Springer. Bibcode:2011LNP...821.....G. doi:10.1007/978-3-642-14382-3. ISBN 978-3-642-14381-6.
  7. ^ A. Karch; E. Katz; D. T. Son; M. A. Stephanov (2006). "Linear Confinement and AdS/QCD". Physical Review D. 74 (1): 015005. arXiv:hep-ph/0602229. Bibcode:2006PhRvD..74a5005K. doi:10.1103/PhysRevD.74.015005. S2CID 16228097.
  8. ^ Andreev, O.; Zakharov, V. I. (2006). "Heavy-quark potentials and AdS/QCD". Phys. Rev. D. 74 (25023): 025023. arXiv:hep-ph/0604204. Bibcode:2006PhRvD..74b5023A. doi:10.1103/PhysRevD.74.025023. S2CID 119391222.
  9. ^ Trawinski, A. P.; Glazek, S. D.; Brodsky, S. J.; de Teramond, G. F.; Dosch, H. G. (2014). "Effective confining potentials for QCD". Phys. Rev. D. 90 (74017): 074017. arXiv:1403.5651. Bibcode:2014PhRvD..90g4017T. doi:10.1103/PhysRevD.90.074017. S2CID 118644867.