Entropy, confinement, and chiral symmetry breaking

Abstract

This paper studies the way in which confinement leads to chiral symmetry breaking (CSB) through a gap equation. We argue that entropic effects cut off infrared singularities in the standard confining effective propagator 1/p4, which should be replaced by 1/(p2+m2)2 for a finite mass m KF/M(0) [M(0) is the zero-momentum value of the running quark mass]. Extension of an old calculation of the author yields a specific estimate for m. This cutoff propagator shows semi-quantitatively two critical properties of confinement: 1) a negative contribution to the confining potential coming from entropic forces; 2) an infrared cutoff required by gauge invariance and CSB itself. Entropic effects lead to a proliferation of pion branches and a qq condensate, and contribute a negative term -KF/M(0) to the effective pion Hamiltonian allowing for a massless pion in the presence of positive kinetic energy and string energy. The resulting gap equation leads to a well-behaved running constituent quark mass M(p2) with M2(0)≈ KF/π. We include one-gluon terms to get the correct renormalization-group ultraviolet behavior, with the improvement that the prefactor (related to <qq>) can be calculated from the confining solution. We discuss an integrability condition that guarantees the absence of IR singularities at m=0 in Minkowski space through use of a principal-part propagator.