华东师范大学学报(自然科学版) >

2022 , Vol. 2022 >Issue 4: 103 - 113

DOI: https://doi.org/10.3969/j.issn.1000-5641.2022.04.010

物理学与电子学

SU(3)协变手征有效理论与八重态重子质量修正

  • 刘舟 ,
  • 杨继锋
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  • 华东师范大学 物理与电子科学学院, 上海 200241

收稿日期: 2021-04-20

  网络出版日期: 2022-07-19

基金资助

国家自然科学基金 (11435005)

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SU(3) covariant chiral effective theory and corrections to the octet baryon masses

  • Zhou LIU ,
  • Jifeng YANG
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  • School of Physics and Electronic Science, East China Normal University, Shanghai 200241, China

Received date: 2021-04-20

  Online published: 2022-07-19

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摘要

在SU(3)协变手征有效理论框架下, 计算了基于奇异夸克贡献的八重态、十重态重子对八重态重子质量的一圈图修正; 发现破坏手征幂律规则的都是定域项, 可通过定域抵消项减除, 从而指向一个更为简洁的减除方案? 扩展的极小减除(Extended Minimal Subtraction, ${\text{E}}\overline {{\text{MS}}} $ )方案; 除了手征贡献, 计算还保留了相对论修正项. 这对精确计算重子质量的修正有价值, 并对解析外推有重要贡献.

关键词: 协变手征有效场论; 八重态重子; 手征幂律规则; ${\text{E}}\overline {{\text{MS}}} $方案

本文引用格式

刘舟 , 杨继锋 . SU(3)协变手征有效理论与八重态重子质量修正[J]. 华东师范大学学报(自然科学版), 2022 , 2022(4) : 103 -113 . DOI: 10.3969/j.issn.1000-5641.2022.04.010

Abstract

In this paper, corrections to the octet baryon masses based on the strange quark contribution are calculated using the SU(3) covariant chiral effective theory. We find that the items violating chiral power counting rules are local and can be subtracted by local counterterms which leads to extended minimal subtraction ${(\text{E}}\overline {{\text{MS}}})$ scheme. In addition to the chiral contribution, relativistic correction items are also retained, which is meaningful for accurately calculating the corrections to baryon masses and analytical extrapolation.

Key words: covariant chiral effective field theory; octet baryons; chiral power counting rules; ${\text{E}}\overline {{\text{MS}}} $scheme

参考文献

1 WILSON K G. Confinement of Quarks. Physical Review, 1974, D10, 2445- 2459.
2 WEINBERG S. Phenomenological Lagrangians. Physica A, 1979, 96 (1/2): 327- 340.
3 GASSER J, LEUTWYER H. Chiral perturbation theory to one loop. Annals of Physics, 1984, 158, 142- 210.
4 GASSER J, LEUTWYER H. Chiral perturbation theory: Expansions in the mass of the strange quark. Nuclear Physics B, 1985, 250, 465- 516.
5 JENKINS E, MANOHAR A V. Baryon chiral perturbation theory using a heavy fermion lagrangian. Physics Letter B, 1991, 255, 558- 562.
6 BECHER T, LEUTWYLER H. Baryon chiral perturbation theory in manifestly Lorentz invariant form. European Physical Journal, 1999, C9, 643- 671.
7 FUCHS T, GEGELIA J, JAPARIDZE G, et al. Renormalization of relativistic baryon chiral perturbation theory and power counting. Physical Review D, 2003, 68, 056005.
8 YANG J F. Anomalous “mapping” between pionfull and pionless EFT’s. Modern Physics Letters A, 2014, 29 (9): 1450043.
9 温莉宏. 强子结构的协变手征有效理论分析 [D]. 上海: 华东师范大学, 2018.
10 王彦. 矢量介子协变手征有效理论研究 [D]. 上海: 华东师范大学, 2020.
11 孙进. 核子-核子散射协变手征有效场论的两圈图研究 [D]. 上海: 华东师范大学, 2020.
12 LIU Z, WEN L H, YANG J F. Covariant propagator and chiral power counting. Nuclear Physics B, 2021, 963, 115288.
13 BIJNENS J, SONODA H, WISE M B. On the validity of chiral perturbation theory for weak hyperon decays. Nuclear Physics B, 1985, B261, 185- 198.
14 JENKINS E. Baryon masses in chiral perturbation theory. Nuclear Physics B, 1992, 368, 190- 203.
15 SALAMU Y, JI C R, MELNITCHOUK W, et al. Parton distributions from nonlocal chiral SU(3) effective theory: Splitting functions. Physical Review D, 2019, 99 (1): 014041.
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