Nucleon Momentum Fraction, Helicity and Transversity from 2+1-flavor Lattice QCD

TL;DR

This paper presents high-precision lattice QCD calculations of nucleon momentum, helicity, and transversity moments, carefully analyzing excited state effects and finite-volume corrections, resulting in values consistent with experimental and other lattice results.

Contribution

The study provides the first comprehensive analysis of excited-state contributions and finite-volume effects in nucleon structure calculations using 2+1-flavor Wilson-clover lattice QCD.

Findings

Results are stable across lattice spacings.

Finite-volume effects are observed but manageable.

Final moments agree with phenomenological fits.

Abstract

High statistics results for the isovector momentum fraction, $\langle x \rangle_{u-d}$, helicity moment, $\langle x \rangle_{\Delta u-\Delta d}$, and the transversity moment, $\langle x\rangle_{\delta u-\delta d}$, of the nucleon are presented using seven ensembles of gauge configurations generated by the JLab/W&M/LANL/MIT collaborations using $2+1$-flavors of dynamical Wilson-clover quarks. Attention is given to understanding and controlling the contributions of excited states. The final results are obtained using a simultaneous fit in the lattice spacing $a$, pion mass $M_\pi$ and the finite volume parameter $M_\pi L$ keeping leading order corrections. The data show no significant dependence on the lattice spacing and some evidence for finite-volume corrections. The main variation is with $M_\pi$, whose magnitude depends on the mass gap of the first excited state used in the analysis. Our final results, in the $\overline{\rm MS}$ scheme at 2 GeV, are $\langle x \rangle_{u-d} = 0.160(16)(20)$, $\langle x \rangle_{\Delta u-\Delta d} = 0.192(13)(20)$ and $\langle x \rangle_{\delta u-\delta d} = 0.215(17)(20)$, where the first error is the overall analysis uncertainty assuming excited-state contributions have been removed, and the second is an additional systematic uncertainty due to possible residual excited-state contributions. These results are consistent with other recent lattice calculations and phenomenological global fit values.