SU(3) Gauge Symmetry: An Experimental Review of Diffractive Physics in e+p, p+p, p+A, and A+A Collision Systems

arXiv - PHYS - Nuclear Experiment Pub Date : 2024-07-23 DOI:arxiv-2407.16835

Krista L. Smith

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Abstract

This review focuses on diffractive physics, which involves the long-range interactions of the strong nuclear force at high energies described by SU(3) gauge symmetry. It is expected that diffractive processes account for nearly 40% of the total cross-section at LHC energies. These processes consist of soft-scale physics where perturbation theory cannot be applied. Although highly successful and often described as a perfect theory, quantum chromodynamics relies heavily on perturbation theory, a model best suited for hard-scale physics. The study of pomerons could help bridge the soft and hard processes and provide a complete description of the theory of the strong interaction across the full momentum spectrum. Here, we will discuss some of the features of diffractive physics, experimental results from SPS, HERA, and the LHC, and where the field could potentially lead. With the recent publication of the odderon discovery in 2021 by the D0 and TOTEM collaborations and the new horizon of physics that lies ahead with the upcoming Electron-Ion Collider at Brookhaven National Laboratory, interest is seemingly piquing in high energy diffractive physics.

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SU(3)计量对称：e+p、p+p、p+A 和 A+A 碰撞系统中衍射物理学的实验回顾

这篇综述的重点是衍射物理学，它涉及苏（3）规对称性描述的高能强核力的长程相互作用。预计衍射过程将占大型强子对撞机能量下总截面的近 40%。这些过程包括无法应用扰动理论的软尺度物理。尽管量子色动力学非常成功，而且经常被描述为完美的理论，但它在很大程度上依赖于微扰理论，而微扰理论是最适合硬尺度物理学的模型。对波美子的研究有助于弥合软过程和硬过程，并提供对整个动量谱的强相互作用理论的完整描述。在此，我们将讨论衍射物理学的一些特征，来自 SPS、HERA 和大型强子对撞机的实验结果，以及该领域可能的发展方向。最近，D0 和 TOTEM 合作小组公布了 2021 年的菟丝子发现，而即将在布鲁克海文国家实验室（Brookhaven National Laboratory）投入使用的电子-离子对撞机又将开创物理学的新纪元，人们似乎对高能衍射物理学产生了浓厚的兴趣。

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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arXiv - PHYS - Nuclear Experiment

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