Structure of the Nucleon and its Excitations

arXiv: High Energy Physics - Lattice Pub Date : 2017-11-15 DOI:10.1051/epjconf/201817506019

W. Kamleh, D. Leinweber, Zhanfeng Liu, F. Stokes, A. Thomas, Samuel Thomas, Jia-Jun Wu

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引用次数: 2

Abstract

The structure of the ground state nucleon and its finite-volume excitations are examined from three different perspectives. Using new techniques to extract the relativistic components of the nucleon wave function, the node structure of both the upper and lower components of the nucleon wave function are illustrated. A non-trivial role for gluonic components is manifest. In the second approach, the parity-expanded variational analysis (PEVA) technique is utilised to isolate states at finite momenta, enabling a novel examination of the electric and magnetic form factors of nucleon excitations. Here the magnetic form factors of low-lying odd-parity nucleons are particularly interesting. Finally, the structure of the nucleon spectrum is examined in a Hamiltonian effective field theory analysis incorporating recent lattice-QCD determinations of low-lying two-particle scattering-state energies in the finite volume. The Roper resonance of Nature is observed to originate from multi-particle coupled-channel interactions while the first radial excitation of the nucleon sits much higher at approximately 1.9 GeV.

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核子的结构及其激发

从三个不同的角度研究了基态核子的结构及其有限体积激发。利用新技术提取了核子波函数的相对论性分量，给出了核子波函数上下分量的节点结构。胶子成分的重要作用是显而易见的。在第二种方法中，利用宇称扩展变分分析(PEVA)技术来隔离有限动量下的状态，从而能够对核子激发的电和磁形式因子进行新颖的检查。这里，低洼奇宇称核子的磁形因子特别有趣。最后，在哈密顿有效场论分析中，结合最近有限体积内低洼双粒子散射态能量的晶格- qcd测定，检验了核子谱的结构。自然界的Roper共振是由多粒子耦合通道相互作用产生的，而核子的第一次径向激发约为1.9 GeV。

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: High Energy Physics - Lattice

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