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Lattice continuum-limit study of nucleon quasi-PDFs

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arxiv 2011.00964 v3 pith:C6EOCUSG submitted 2020-11-02 hep-lat hep-phnucl-th

Lattice continuum-limit study of nucleon quasi-PDFs

classification hep-lat hep-phnucl-th
keywords latticeapproachcontinuumdistributionextrapolationmassmomentumnucleon
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The quasi-PDF approach provides a path to computing parton distribution functions (PDFs) using lattice QCD. This approach requires matrix elements of a power-divergent operator in a nucleon at high momentum and one generically expects discretization effects starting at first order in the lattice spacing $a$. Therefore, it is important to demonstrate that the continuum limit can be reliably taken and to understand the size and shape of lattice artifacts. In this work, we report a calculation of isovector unpolarized and helicity PDFs using lattice ensembles with $N_f=2+1+1$ Wilson twisted mass fermions, a pion mass of approximately 370 MeV, and three different lattice spacings. Our results show a significant dependence on $a$, and the continuum extrapolation produces a better agreement with phenomenology. The latter is particularly true for the antiquark distribution at small momentum fraction $x$, where the extrapolation changes its sign.

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