Abstract
The relative contributions of explicit and dynamical chiral symmetry breaking in QCD models of the quark-gap equation are studied in dependence of frequently employed ans\"atze for the dressed interaction and quark-gluon vertex. The explicit symmetry breaking contributions are defined by a constituent-quark sigma term whereas the combined effects of explicit and dynamical symmetry breaking are described by a Euclidean constituent-mass solution. We extend this study of the gap equation to a quark-gluon vertex beyond the Abelian approximation complemented with numerical gluon- and ghost-dressing functions from lattice QCD. We find that the ratio of the sigma term over the Euclidean mass is largely independent of nonperturbative interaction and vertex models for current-quark masses, $m_{u,d}(\mu) \leq m(\mu) \leq m_b(\mu)$, and equal contributions of explicit and dynamical chiral symmetry breaking occur at $m(\mu) \approx 400$~MeV. For massive solutions of the gap equation with lattice propagators this value decreases to about 200~MeV.
Highlights
The relative contributions of explicit and dynamical chiral symmetry breaking in quantum chromodynamics (QCD) models of the quark-gap equation are studied in dependence of frequently employed Ansätze for the dressed interaction and quark-gluon vertex
We extend this study of the gap equation to a quark-gluon vertex beyond the Abelian approximation complemented with numerical gluon- and ghost-dressing functions from lattice QCD
We find that the ratio of the sigma term over the Euclidean mass is largely independent of nonperturbative interaction and vertex models for current-quark masses, mu;dðμÞ ≤ mðμÞ ≤ mbðμÞ, and equal contributions of explicit and dynamical chiral symmetry breaking occur at mðμÞ ≈ 400 MeV
Summary
Strong interactions are singularly characterized by a most effective mass-generating mechanism driven by dynamical chiral symmetry breaking (DCSB). It turns out that the contributions of CSB and DCSB to the constituent-quark mass are approximately similar halfway between the strange and charm currentquark masses in the leading symmetry-preserving truncation of the quark’s DSE and given functional form of the model interaction, namely the Maris-Tandy (MT) model [37]. For a given flavor and interaction tuned to reproduce light-hadron observables, the Euclidean mass MEf varies in a range of about 20%–30% The extension of this numerical study to a gap equation with gluon and ghost propagators obtained with lattice QCD simulations mirrors the findings with model interactions
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