Topology and chiral symmetry breaking in QCD

Abstract

We construct a model to study the impact of instantons on the low lying eigenvalue spectrum of the Dirac operator. The model is by necessity, approximate, though it does incorporate the important symmetries of the underlying field theory. The model also reproduces classical results in the appropriate limits. We find that generic instanton ensembles lead to an accumulation of eigenvalues around zero, and hence, break chiral symmetry. The eigenvalue spectrum is divergent however, as the eigenvalue approaches zero. This leads to a divergent chiral condensate in quenched QCD, and hence, shows the theory to be pathological. In full QCD we find the novel result of a divergent spectral density leading to chiral symmetry breaking, but, with a finite condensate. This result holds for both Nf=1 and Nf=2. We also compute correlation functions and find a massive η' and σ in the chiral limit. Whilst the divergence follows a power law, the strength of the divergence is inversely proportional to the instanton density. To investigate the impact of the divergence further, we analyse instanton ensembles derived by "cooling" lattice gauge configurations. An important negative result is that the chiral condensate is strongly dependent upon the number of cooling sweeps performed. Whether the problem lies with cooling or with the identification of topological objects is yet to be resolved.

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