Predicting $\sin(2\phi-\phi_{s})$ azimuthal asymmetry in pion-proton induced Drell-Yan process using holographic light-front QCD

TL;DR

This paper predicts the azimuthal asymmetry in pion-proton Drell-Yan processes using holographic light-front QCD, highlighting the importance of nonperturbative effects and gluon rescattering in TMDs.

Contribution

It introduces a holographic light-front QCD framework to calculate TMDs and azimuthal asymmetries, incorporating nonperturbative gluon rescattering effects.

Findings

Nonzero pion Boer-Mulders TMD due to gluon rescattering

Effective nonperturbative SU(3) gluon rescattering kernel

Predicted azimuthal asymmetry in pion-proton Drell-Yan process

Abstract

We compute the $\sin(2\phi-\phi_{s})$ azimuthal asymmetry in the pion-nucleon induced Drell-Yan process within transverse momentum dependent factorization. We employ the holographic light-front pion wave functions to calculate its leading-twist transverse momentum dependent parton distributions (TMDs). The Boer-Mulders TMD of the pion is then convoluted with the transversity TMD of the proton evaluated in a light-front quark-diquark model constructed with the wave functions predicted by the soft-wall AdS/QCD to obtain the azimuthal asymmetry in the Drell-Yan process. The gluon rescattering is pivotal to predict nonzero pion Boer-Mulders TMD. We investigate the utility of a nonperturbative SU$(3)$ gluon rescattering kernel going beyond the usual approximation of perturbative U$(1)$ gluons. The holographic light-front QCD approach provides a powerful tool for exploring the role of nonperturbative QCD effects in the Drell-Yan process and may help to guide future experimental measurements.