Nonperturbative quantization \`a la Heisenberg for non-Abelian gauge theories: two-equation approximation

Abstract

The nonperturbative quantization technique \`a la Heisenberg is applied for non-Abelian gauge theories. The operator Yang-Mills equation is written, which on the corresponding averaging gives an infinite set of equations for all Green functions. We split all degrees of freedom into two groups: in the former, we have Aaμ ∈ G ⊂ SU(N), and in the second group we have coset degrees of freedom SU(N) / G. Using such splitting and some assumptions about 2- and 4-point Green functions, we truncate the infinite set of equations to two equations. The first equation is for the gauge fields from the subgroup G, and the second equation is for a gluon condensate which is the dispersion of quantum fluctuations of the coset fields. Two examples are considered: The first one is a flux tube solution describing longitudinal color electric fields stretched between quark and antiquark located at the infinities. The second one is a flux tube stretched between two quarks (antiquarks) located at ∞. A special case is considered when the longitudinal electric field produced by a quark located at + ∞ is equal and oppositely directed to the field generated by a quark located at - ∞ that leads to zero total electric field. Both solutions represents the dual Meissner effect: the electric field is pushed out from the gluon condensate.