Theoretical estimate on tensor-polarization asymmetry in proton-deuteron Drell-Yan process

TL;DR

This paper provides a theoretical estimate of tensor-polarization asymmetry in proton-deuteron Drell-Yan processes, aiming to explore tensor-polarized parton distributions and their implications for high-energy spin physics.

Contribution

It introduces a theoretical estimate of tensor-polarization asymmetry in proton-deuteron Drell-Yan processes using optimized tensor-polarized PDFs, highlighting potential for new hadron physics insights.

Findings

Asymmetry is typically a few percent in the proposed experiment.

Significant tensor-polarized gluon distribution likely exists due to Q^2 evolution.

Tensor-polarized gluon distribution has not been observed yet.

Abstract

Tensor-polarized parton distribution functions are new quantities in spin-one hadrons such as the deuteron, and they could probe new quark-gluon dynamics in hadron and nuclear physics. In charged-lepton deep inelastic scattering (DIS), they are studied by the twist-two structure functions $b_1$ and $b_2$. The HERMES collaboration found unexpectedly large $b_1$ values than a naive theoretical expectation based on the standard deuteron model. The situation should be significantly improved in the near future by an approved experiment to measure $b_1$ at JLab (Thomas Jefferson National Accelerator Facility). There is also an interesting indication in the HERMES result that finite antiquark tensor polarization exists. It could play an important role in solving a mechanism on tensor structure in the quark-gluon level. The tensor-polarized antiquark distributions are not easily determined from the charged-lepton DIS; however, they can be measured in a proton-deuteron Drell-Yan process with a tensor-polarized deuteron target. In this article, we estimate the tensor-polarization asymmetry for a possible Fermilab Main-Injector experiment by using optimum tensor-polarized PDFs to explain the HERMES measurement. We find that the asymmetry is typically a few percent. If it is measured, it could probe new hadron physics, and such studies could create an interesting field of high-energy spin physics. In addition, we find that a significant tensor-polarized gluon distribution should exist due to $Q^2$ evolution, even if it were zero at a low $Q^2$ scale. The tensor-polarized gluon distribution has never been observed, so that it is an interesting future project.