Towards the QCD String: 2+1 dimensional Yang-Mills theory in the planar limit
Abstract
We study the large N (planar) limit of pure SU(N) 2+1 dimensional Yang-Mills theory (YM2+1) using a gauge-invariant matrix parameterization introduced by Karabali and Nair. This formulation crucially relies on the properties of local holomorphic gauge invariant collective fields in the Hamiltonian formulation of YM2+1. We show that the spectrum in the planar limit of this theory can be explicitly determined in the N=∞, low momentum (large 't Hooft coupling) limit, using the technology of the Eguchi-Kawai reduction and the existing knowledge concerning the one-matrix model. The dispersion relation describing the planar YM2+1 spectrum reads as ω(k) = k2 + mn2, where n=1,2,... and mn = n mr, where mr denotes the renormalized mass, the bare mass m being determined by the planar 't Hooft coupling gYM2 N via m= gYM2 N2 π. The planar, low momentum limit, also captures the expected short and long distance physics of YM2+1 and gives an interesting new picture of confinement. The computation of the spectrum is possible due to a reduction of the YM2+1 Hamiltonian for the large 't Hooft coupling to the singlet sector of an effective one matrix model. The crucial observation is that the correct vacuum (the large N master field), consistent with the area law and the existence of a mass gap, is described by an effective quadratic matrix model, in the large N, large 't Hooft coupling limit.
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