Analytical Relation between Quark Confinement and Chiral Symmetry Breaking in QCD

Abstract

We study the relation between quark confinement and spontaneous chiral-symmetry breaking directly in QCD. In lattice QCD formalism, we derive an analytical gauge-invariant relation between the Polyakov loop LP and the Dirac eigenvalues λn, i.e., LP Σn λnNt -1 n| U4|n , on a temporally odd-number lattice, where the temporal lattice size Nt is odd. Here, |n denotes the Dirac eigenmode, i.e., D|n =iλn|n , and U4 the temporal link-variable operator. We here use an ordinary square lattice with the normal periodic boundary condition for link-variables Uμ(s) in the temporal direction. Because of the factor λnNt -1 in the analytical relation, the contribution of low-lying Dirac modes to the Polyakov loop is negligibly small in both confined and deconfined phases, while the low-lying Dirac modes are essential for chiral symmetry breaking. Also, in lattice QCD simulations, we numerically confirm the analytical relation, non-zero finiteness of n| U4|n for each Dirac mode, and negligibly small contribution of low-lying Dirac modes to the Polyakov loop. Thus, we conclude that low-lying Dirac modes are not essential for confinement, which indicates no direct one-to-one correspondence between confinement and chiral symmetry breaking in QCD.