Correlated Dirac Eigenvalues and Axial Anomaly in Chiral Symmetric QCD
Abstract
We investigate the Dirac eigenvalue spectrum ((λ,ml)) to study the microscopic origin of axial anomaly in high temperature phase of QCD. We propose novel relations between the derivatives (∂n (λ,ml)/∂ mln) of the Dirac eigenvalue spectrum with respect to the quark mass (ml) and the (n+1)-point correlations among the eigenvalues (λ) of the massless Dirac operator. Based on these relations, we present lattice QCD results for ∂n (λ,ml)/∂ mln (n=1, 2, 3) with ml corresponding to pion masses mπ=160-55 MeV, and at a temperature of about 1.6 times the chiral phase transition temperature. Calculations were carried out using (2+1)-flavors of highly improved staggered quarks and the tree-level Symanzik gauge action with the physical strange quark mass, three lattice spacings a=0.12, 0.08, 0.06 fm, and lattices having aspect ratios 4-9. We find that (λ0,ml) develops a peaked structure. This peaked structure, which arises due to non-Poisson correlations within the infrared part of the Dirac eigenvalue spectrum, becomes sharper as a0, and its amplitude is proportional to ml2. After continuum and chiral extrapolations, we find that the axial anomaly remains manifested in two-point correlation functions of scalar and pseudo-scalar mesons in the chiral limit. We demonstrate that the behavior of (λ0,ml) is responsible for it.
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