Color-magnetic correlations in SU(N) lattice QCD
Abstract
Motivated by color-magnetic instabilities in QCD, we investigate field-strength correlations in both SU(2) and SU(3) lattice QCD. In the Euclidean Landau gauge, we numerically calculate the perpendicular-type color-magnetic correlation, C(r) g2 Hza(s)Hza(s + r )) with x, y, and the parallel-type one, C(r) g2 Hza(s)Hza(s + r ) with ~ z, t. In the Landau gauge, all two-point field-strength correlations g2 Gaμ(s)Gbαβ(s') are described by these two quantities, due to the Lorentz and global SU(Nc) color symmetries. Curiously, the perpendicular-type color-magnetic correlation C(r) is found to be always negative for arbitrary r, except for the same point of r=0. The parallel-type color-magnetic correlation C(r) is always positive. In the infrared region, C(r) and C(r) strongly cancel each other, which leads to an approximate cancellation for the sum of the field-strength correlations as Σμ, Gaμ(s)Gaμ(s') C(|s-s'|)+ C(|s-s'|) 0. Next, we decompose the perpendicular-type color-magnetic correlation C(r) into quadratic, cubic and quartic terms of the gluon field Aμ. The quadratic term is always negative, which is explained by the Yukawa-type gluon propagator Aaμ(s)Aaμ(s') e-mr/r with r |s-s'| in the Landau gauge. The quartic term gives a relatively small contribution. In the infrared region, the cubic term is positive and tends to cancel with the quadratic term, resulting in a small value of C(r).
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