Exploring baryon resonances with transition generalized parton distributions: status and perspectives

IF 2.8 3区物理与天体物理 Q2 PHYSICS, NUCLEAR

The European Physical Journal A Pub Date : 2025-06-06 DOI:10.1140/epja/s10050-025-01552-2

S. Diehl, K. Joo, K. Semenov-Tian-Shansky, C. Weiss, V. Braun, W. C. Chang, P. Chatagnon, M. Constantinou, Y. Guo, P. T. P. Hutauruk, H. S. Jo, A. Kim, J.-Y. Kim, P. Kroll, S. Kumano, C.-H. Lee, S. Liuti, R. McNulty, H.-D. Son, P. Sznajder, A. Usman, C. Van Hulse, M. Vanderhaeghen, M. Winn

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引用次数: 0

Abstract

QCD gives rise to a rich spectrum of excited baryon states. Understanding their internal structure is important for many areas of nuclear physics, such as nuclear forces, dense matter, and neutrino-nucleus interactions. Generalized parton distributions (GPDs) are an established tool for characterizing the QCD structure of the ground-state nucleon. They are used to create 3D tomographic images of the quark/gluon structure and quantify the mechanical properties such as the distribution of mass, angular momentum, and forces in the system. Transition GPDs extend these concepts to \(N \rightarrow N^*\) transitions and can be used to characterize the 3D structure and mechanical properties of baryon resonances. They can be probed in high-momentum-transfer exclusive electroproduction processes with resonance transitions \(e + N \rightarrow e' + M + N^*\), such as deeply-virtual Compton scattering (\(M = \gamma \)) or meson production (\(M = \pi , K\), etc.), and in related photon/hadron-induced processes. This White Paper describes a research program aiming to explore baryon resonance structure with transition GPDs. This includes the properties and interpretation of the transition GPDs, theoretical methods for structures and processes, first experimental results from JLab 12 GeV, future measurements with existing and planned facilities (JLab detector and energy upgrades, COMPASS/AMBER, EIC, EicC, J-PARC, LHC ultraperipheral collisions), and the theoretical and experimental developments needed to realize this program.

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利用跃迁广义部子分布探索重子共振：现状与展望

QCD产生了丰富的激发态重子谱。了解它们的内部结构对核物理学的许多领域都很重要，例如核力、致密物质和中微子-核相互作用。广义部分子分布（GPDs）是表征基态核子QCD结构的常用工具。它们被用来创建夸克/胶子结构的三维层析图像，并量化力学特性，如质量分布、角动量和系统中的力。跃迁gpd将这些概念扩展到\(N \rightarrow N^*\)跃迁，并可用于表征重子共振的3D结构和力学特性。它们可以在共振跃迁\(e + N \rightarrow e' + M + N^*\)的高动量转移专用电生产过程中进行探测，例如深虚拟康普顿散射（\(M = \gamma \)）或介子产生（\(M = \pi , K\)等），以及相关的光子/强子诱导过程。本白皮书介绍了一项旨在探索跃迁gpd重子共振结构的研究计划。这包括跃迁gpd的性质和解释，结构和过程的理论方法，JLab 12 GeV的首次实验结果，现有和计划中的设施（JLab探测器和能量升级，COMPASS/AMBER， EIC, EicC, J-PARC， LHC超外围碰撞）的未来测量，以及实现该计划所需的理论和实验发展。

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来源期刊

The European Physical Journal A 物理-物理：核物理

CiteScore

5.00

自引率

18.50%

发文量

216

审稿时长

3-8 weeks

期刊介绍： Hadron Physics Hadron Structure Hadron Spectroscopy Hadronic and Electroweak Interactions of Hadrons Nonperturbative Approaches to QCD Phenomenological Approaches to Hadron Physics Nuclear and Quark Matter Heavy-Ion Collisions Phase Diagram of the Strong Interaction Hard Probes Quark-Gluon Plasma and Hadronic Matter Relativistic Transport and Hydrodynamics Compact Stars Nuclear Physics Nuclear Structure and Reactions Few-Body Systems Radioactive Beams Electroweak Interactions Nuclear Astrophysics Article Categories Letters (Open Access) Regular Articles New Tools and Techniques Reviews.