We review results for the phase diagram of QCD, the properties of quarks and gluons and
the resulting properties of strongly interacting matter at finite temperature and chemical …

Recent studies of QCD Green's functions and their applications in hadronic physics are
reviewed. We discuss the definition of the generating functional in gauge theories, in …

We review the spectrum and electromagnetic properties of baryons described as relativistic
three-quark bound states within QCD. The composite nature of baryons results in a rich …

Dyson–Schwinger equations furnish a Poincaré covariant framework within which to study
hadrons. A particular feature is the existence of a nonperturbative, symmetry preserving …

I review recent results on the infrared properties of QCD from Dyson–Schwinger equations.
The topics include infrared exponents of one-particle irreducible Green's functions, the fixed …

We present the first Dyson–Schwinger calculation of the three-gluon vertex in Landau-
gauge QCD in which its full covariant structure is back-coupled self-consistently. We truncate …

We calculate the pion's valence-quark momentum-fraction probability distribution using a
Dyson-Schwinger equation model. Valence quarks with an active mass of 0.30 GeV carry …

An overview of the theory and phenomenology of hadrons and QCD is provided from a
Dyson–Schwinger equation viewpoint. Following a discussion of the definition and …

We present a unified study of nucleon and\({\Delta}\) elastic and transition form factors, and
compare predictions made using a framework built upon a Faddeev equation kernel and …

We report the first study of the nucleon where the full Poincaré-covariant structure of the
three-quark amplitude is implemented in the Faddeev equation. We employ an interaction …