Phase of the Wilson Line

Abstract

This paper discusses the global Z(N) symmetry of finite-temperature, SU(N), pure Yang-Mills lattice gauge theory and the physics of the phase of the Wilson line expectation value. In the high T phase, L takes one of N distinct values proportional to the Nth roots of unity in Z(N), and the Z(N) symmetry is broken. Only one of these is consistent with the usual interpretation L = e-F/T. This relation should be generalized to L = z e-F/T with z ∈ Z(N) so that it is consistent with the negative or complex values. In the Hamiltonian description, the physical variables are the group elements on the links of the spatial lattice. In a Lagrangian formulation, there are also group elements on links in the inverse-temperature direction from which the Wilson line is constructed. These are unphysical, auxiliary variables introduced to enforce the Gauss law constraints. The following results are obtained: The relation L =ze-F/T is derived. The value of z ∈ Z(N) is determined by the external field that is needed for the infinite-volume limit. There is a single physical, high-temperature phase, which is the same for all z. The global Z(N) symmetry is not physical; it acts as the identity on all physical states. In the Hamiltonian formulation, the high-temperature phase is not distinguished by physical broken symmetry but rather by percolating flux.

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