TY - JOUR
T1 - Confinement
T2 - Understanding the relation between the Wilson loop and dual theories of long distance Yang-Mills theory
AU - Baker, M.
AU - Ball, J. S.
AU - Brambilla, N.
AU - Prosperi, G. M.
AU - Zachariasen, F.
PY - 1996
Y1 - 1996
N2 - In this paper we express the velocity-dependent, spin-dependent heavy quark potential [Formula presented] in QCD in terms of a Wilson loop [Formula presented] determined by pure Yang-Mills theory. We use an effective dual theory of long-distance Yang-Mills theory to calculate [Formula presented] for large loops, i.e., for loops of size [Formula presented]. [[Formula presented] is the flux tube radius, fixed by the value of the Higgs (monopole) mass of the dual theory, which is a concrete realization of the Mandelstam-'t Hooft dual superconductor mechanism of confinement.] We replace [Formula presented] by [Formula presented], given by a functional integral over the dual variables, which for [Formula presented] can be evaluated by a semiclassical expansion, since the dual theory is weakly coupled at these distances. The classical approximation gives the leading contribution to [Formula presented] and yields a velocity-dependent heavy quark potential that for large [Formula presented] becomes linear in [Formula presented], and that for small [Formula presented] approaches lowest-order perturbative QCD. This latter fact means that these results should remain applicable down to distances where radiative corrections giving rise to a running coupling constant become important. The spin dependence of the potential at long range as well as at short range reflects the vector coupling of quarks in QCD combined with the dual treatment of long-distance Yang-Mills theory. The methods developed here should be applicable to any realization of the dual superconductor mechanism. They give an expression determining [Formula presented] independent of the classical approximation, but semiclassical corrections due to fluctuations of the flux tube are not worked out in this paper. Taking these into account should lead to an effective string theory free from the conformal anomaly.
AB - In this paper we express the velocity-dependent, spin-dependent heavy quark potential [Formula presented] in QCD in terms of a Wilson loop [Formula presented] determined by pure Yang-Mills theory. We use an effective dual theory of long-distance Yang-Mills theory to calculate [Formula presented] for large loops, i.e., for loops of size [Formula presented]. [[Formula presented] is the flux tube radius, fixed by the value of the Higgs (monopole) mass of the dual theory, which is a concrete realization of the Mandelstam-'t Hooft dual superconductor mechanism of confinement.] We replace [Formula presented] by [Formula presented], given by a functional integral over the dual variables, which for [Formula presented] can be evaluated by a semiclassical expansion, since the dual theory is weakly coupled at these distances. The classical approximation gives the leading contribution to [Formula presented] and yields a velocity-dependent heavy quark potential that for large [Formula presented] becomes linear in [Formula presented], and that for small [Formula presented] approaches lowest-order perturbative QCD. This latter fact means that these results should remain applicable down to distances where radiative corrections giving rise to a running coupling constant become important. The spin dependence of the potential at long range as well as at short range reflects the vector coupling of quarks in QCD combined with the dual treatment of long-distance Yang-Mills theory. The methods developed here should be applicable to any realization of the dual superconductor mechanism. They give an expression determining [Formula presented] independent of the classical approximation, but semiclassical corrections due to fluctuations of the flux tube are not worked out in this paper. Taking these into account should lead to an effective string theory free from the conformal anomaly.
UR - http://www.scopus.com/inward/record.url?scp=0000396237&partnerID=8YFLogxK
U2 - 10.1103/PhysRevD.54.2829
DO - 10.1103/PhysRevD.54.2829
M3 - Article
AN - SCOPUS:0000396237
SN - 1550-7998
VL - 54
SP - 2829
EP - 2844
JO - Physical Review D - Particles, Fields, Gravitation and Cosmology
JF - Physical Review D - Particles, Fields, Gravitation and Cosmology
IS - 4
ER -