Origin of Confining Force

Abstract

In this article we present exact calculations that substantiate a clear picture relating the confining force of QCD to the zero-modes of the Faddeev-Popov (FP) operator M(A) = - ∂ · D(A). This is done in two steps. First we calculate the spectral decomposition of the FP operator and show that the ghost propagator G(k; A) = k| M-1(A) | k in an external gauge potential A is enhanced at low k in Fourier space for configurations A on the Gribov horizon. This results from the new formula in the low-k regime Gab(k,A) = δab λ|k|-1(gA), where λ|k|(gA) is the eigenvalue of the FP operator that emerges from λ|k|(0) = k2 at A = 0. Next we derive a strict inequality signaling the divergence of the color-Coulomb potential at low momentum k namely, V(k) ≥ k2 G2(k) for k 0, where V(k) is the Fourier transform of the color-Coulomb potential V(r) and G(k) is the ghost propagator in momentum space. The first result holds in the Landau and Coulomb gauges, whereas the second holds in the Coulomb gauge only. We propose a new numerical lattice gauge fixing that should be closer to the present analytic approach than other numerical gauges.