AdS/QCD, Light-Front Holography, and the Nonperturbative Running Coupling

TL;DR

This paper combines AdS/QCD and light-front holography to model hadron spectra, wavefunctions, and the nonperturbative running coupling, providing insights into QCD confinement and matching experimental and lattice data.

Contribution

It introduces a holographic QCD model that accurately predicts hadron spectra and derives a nonperturbative coupling consistent with experimental and lattice results.

Findings

Accurate hadron spectra and wavefunctions from the model

Nonperturbative coupling matches experimental data

The $eta$-function captures key QCD features

Abstract

The combination of Anti-de Sitter space (AdS) methods with light-front (LF) holography provides a remarkably accurate first approximation for the spectra and wavefunctions of meson and baryon light-quark bound states. The resulting bound-state Hamiltonian equation of motion in QCD leads to relativistic light-front wave equations in terms of an invariant impact variable $\zeta$ which measures the separation of the quark and gluonic constituents within the hadron at equal light-front time. These equations of motion in physical space-time are equivalent to the equations of motion which describe the propagation of spin-$J$ modes in anti--de Sitter (AdS) space. The eigenvalues give the hadronic spectrum, and the eigenmodes represent the probability distributions of the hadronic constituents at a given scale. A positive-sign confining dilaton background modifying AdS space gives a very good account of meson and baryon spectroscopy and form factors. The light-front holographic mapping of this model also leads to a non-perturbative effective coupling $\alpha_s^{AdS}(Q^2)$ which agrees with the effective charge defined by the Bjorken sum rule and lattice simulations. It displays a transition from perturbative to nonperturbative conformal regimes at a momentum scale $ \sim 1$ GeV. The resulting $\beta$-function appears to capture the essential characteristics of the full $\beta$-function of QCD, thus giving further support to the application of the gauge/gravity duality to the confining dynamics of strongly coupled QCD.