Transversity from First Principles in QCD

TL;DR

This paper explores how first-principles QCD calculations of light-front wavefunctions can explain transversity observables and phenomena like single-spin asymmetries, factorization breaking, and diffractive scattering, linking theory with experimental data.

Contribution

It demonstrates the use of light-front holography and AdS/QCD to compute hadron wavefunctions and analyze their role in transversity and related QCD phenomena from first principles.

Findings

Light-front wavefunctions explain transversity observables.

Lensing effects cause factorization breaking in QCD.

AdS/QCD models successfully predict hadron spectra.

Abstract

Transversity observables, such as the T-odd single-spin asymmetry measured in deep inelastic lepton scattering on polarized protons, and the distributions which are measured in deeply virtual Compton scattering provide important constraints on the fundamental quark and gluon structure of the proton. In this talk I discuss the challenge of computing these observables from first principles; i.e., quantum chromodynamics, itself. A key step is the determination of the frame-independent light-front wavefunctions (LFWFs) of hadrons -- the QCD eigensolutions which are analogs of the Schrodinger wavefunctions of atomic physics. The lensing effects of initial-state and final-state interactions, acting on LFWFs with different orbital angular momentum, lead to the T-odd transversity observables such as the Sivers, Collins, and Boer-Mulders distributions. The lensing effect also leads to leading-twist phenomena which break leading-twist factorization, such as the breakdown of the Lam-Tung relation in Drell-Yan reactions. A similar rescattering mechanism also leads to diffractive deep inelastic scattering, as well as nuclear shadowing and non-universal antishadowing. It is thus important to distinguish "static" structure functions, the probability distributions computed from the target hadron's light-front wavefunctions, versus "dynamical" structure functions which include the effects of initial- and final-state rescattering. I also discuss related effects, such as the J=0 fixed pole contribution which appears in the real part of the virtual Compton amplitude. AdS/QCD, together with "Light-Front Holography", provides a simple Lorentz-invariant color-confining approximation to QCD which is successful in accounting for light-quark meson and baryon spectroscopy as well as hadronic LFWFs.