Transverse Momentum Distributions from Lattice QCD without Wilson Lines

IF 8.1 1区物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY

Physical review letters Pub Date : 2024-12-13 DOI:10.1103/physrevlett.133.241904

Yong Zhao

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引用次数: 0

Abstract

The transverse-momentum-dependent distributions (TMDs), which are defined by gauge-invariant 3D parton correlators with staple-shaped lightlike Wilson lines, can be calculated from quark and gluon correlators fixed in the Coulomb gauge on a Euclidean lattice. These quantities can be expressed gauge invariantly as the correlators of Coulomb-gauge-dressed fields, which reduce to the standard TMD correlators under principal-value prescription in the infinite boost limit. In the framework of large-momentum effective theory, a quasi-TMD defined from such correlators in a large-momentum hadron state can be matched to the TMD via a factorization formula, whose exact form is derived using soft collinear effective theory and verified at one-loop order. Compared to the currently used gauge-invariant correlators, this new method can substantially improve statistical precision and simplify renormalization for the time-reversal-even TMDs, which will greatly enhance the predicative power of lattice QCD in the nonperturbative region.

Published by the American Physical Society

2024

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横向动量相关分布（TMDs）是由轨规不变的三维部分子相关器与订书钉形轻型威尔逊线定义的，可以从欧几里得晶格上以库仑轨固定的夸克和胶子相关器计算出来。这些量可以用库仑规压制场的相关器来表示，在无限提升极限下，这些相关器可以还原成主值处方下的标准 TMD 相关器。在大量子有效理论的框架内，由大量子强子态中的这种相关子定义的准 TMD 可以通过因式分解公式与 TMD 匹配，其精确形式是用软对偶有效理论推导出来的，并在一环阶上得到了验证。与目前使用的规不变相关器相比，这一新方法可以大幅提高统计精度，并简化时间反转偶TMD的重正化，这将大大提高格子QCD在非微扰区域的预测能力。美国物理学会出版 2024

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Physical review letters 物理-物理：综合

CiteScore

16.50

自引率

7.00%

发文量

2673

审稿时长

2.2 months

期刊介绍： Physical review letters(PRL)covers the full range of applied, fundamental, and interdisciplinary physics research topics: General physics, including statistical and quantum mechanics and quantum information Gravitation, astrophysics, and cosmology Elementary particles and fields Nuclear physics Atomic, molecular, and optical physics Nonlinear dynamics, fluid dynamics, and classical optics Plasma and beam physics Condensed matter and materials physics Polymers, soft matter, biological, climate and interdisciplinary physics, including networks