Self-renormalization of quasi-light-front correlators on the lattice

In applying large-momentum effective theory, renormalization of the Euclidean correlators in lattice regularization is a challenge due to linear divergences in the self-energy of Wilson lines. Based on lattice QCD matrix elements of the quasi-PDF operator at lattice spacing a=0.03fm ∼ 0.12fm with cl...

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Published in:Nuclear physics. B 2021-08, Vol.969 (C), p.115443, Article 115443
Main Authors: Huo, Yi-Kai, Su, Yushan, Gui, Long-Cheng, Ji, Xiangdong, Li, Yuan-Yuan, Liu, Yizhuang, Schäfer, Andreas, Schlemmer, Maximilian, Sun, Peng, Wang, Wei, Yang, Yi-Bo, Zhang, Jian-Hui, Zhang, Kuan
Format: Article
Language:English
Subjects:
NUCLEAR PHYSICS AND RADIATION PHYSICS
Physics
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Summary:In applying large-momentum effective theory, renormalization of the Euclidean correlators in lattice regularization is a challenge due to linear divergences in the self-energy of Wilson lines. Based on lattice QCD matrix elements of the quasi-PDF operator at lattice spacing a=0.03fm ∼ 0.12fm with clover and overlap valence quarks on staggered and domain-wall sea, we design a strategy to disentangle the divergent renormalization factors from finite physics matrix elements, which can be matched to a continuum scheme at short distance such as dimensional regularization and minimal subtraction. Our results indicate that the renormalization factors are universal in the hadron state matrix elements. Moreover, the physical matrix elements appear independent of the valence fermion formulations. These conclusions remain valid even with HYP smearing which reduces the statistical errors albeit reducing control of the renormalization procedure. Moreover, we find a large non-perturbative effect in the popular RI/MOM and ratio renormalization scheme, suggesting favor of the hybrid renormalization procedure proposed recently.
ISSN:0550-3213
1873-1562
DOI:10.1016/j.nuclphysb.2021.115443