Light-front mass operator with dressed quarks

TL;DR

This paper develops a light-front mass operator incorporating quark dressing effects via a running mass, enabling improved nonperturbative QCD modeling of hadron structure.

Contribution

It introduces a dressed mass-squared operator derived from lattice-QCD-inspired propagators, advancing light-front Hamiltonian methods for quark-antiquark systems.

Findings

Quark dressing causes significant infrared modifications.

The framework preserves ultraviolet behavior.

Application to pion structure yields detailed parton distributions.

Abstract

We construct an effective light-front mass-squared operator for quark-antiquark systems that incorporates quark dressing effects through a running quark mass. Starting from a Minkowski-space quark propagator constrained by lattice-QCD-inspired parametrization, we derive the disconnected light-front resolvent for a light quark-antiquark system using a generalized spectral representation of an individual quark propagator separating out the instantaneous contributions. By projecting the resolvent onto a constituent-quark helicity basis, we obtain an effective dressed mass-squared operator suitable for light-front Hamiltonian approaches. We introduce an effective light-front quark self-energy and analyze its momentum dependence. As an application, we study pion structure using representative light-front wave-function models and compute unpolarized transverse-momentum-dependent distributions, unpolarized parton distribution functions and distribution amplitudes. Our results show that quark dressing induces sizable infrared modifications while preserving controlled ultraviolet behavior, providing a framework to incorporate nonperturbative QCD dynamics into light-front descriptions of hadrons.