手性神经网络和3N相互作用对非对称物质计算核对称能的约束

R. Somasundaram, C. Drischler, I. Tews, J. Margueron
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引用次数: 4

摘要

核对称能是核(天文)物理中的一个重要物理量。它描述了核状态方程(EOS)的同位旋依赖关系,通常认为它几乎是二次的。在这项工作中,我们基于一组常用的哈密顿量,包括从手性有效场论导出的两核子力和三核子力,用明确的非对称核物质计算来面对EOS的标准二次展开。我们特别研究了对称能的非二次贡献的重要性,包括Kaiser [Phys]引入的非解析对数项。[j].\textbf{中国}生物医学工程学报,2015,31(5)。我们的研究结果表明,对称能的四次贡献可以从所采用的各种哈密顿量中稳健地确定,并且我们在饱和密度下得到1.00(8)MeV(或0.55(8)MeV的势部分),而对称能的对数贡献相对较小且依赖于模型。最后,我们采用元模型方法研究了高阶贡献对中子星壳核跃迁密度的影响,并发现了5%的小修正。
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Constraints on the nuclear symmetry energy from asymmetric-matter calculations with chiral NN and 3N interactions
The nuclear symmetry energy is a key quantity in nuclear (astro)physics. It describes the isospin dependence of the nuclear equation of state (EOS), which is commonly assumed to be almost quadratic. In this work, we confront this standard quadratic expansion of the EOS with explicit asymmetric nuclear-matter calculations based on a set of commonly used Hamiltonians including two- and three-nucleon forces derived from chiral effective field theory. We study, in particular, the importance of non-quadratic contributions to the symmetry energy, including the non-analytic logarithmic term introduced by Kaiser [Phys.~Rev.~C \textbf{91}, 065201 (2015)]. Our results suggest that the quartic contribution to the symmetry energy can be robustly determined from the various Hamiltonians employed, and we obtain 1.00(8) MeV (or 0.55(8) MeV for the potential part) at saturation density, while the logarithmic contribution to the symmetry energy is relatively small and model-dependent. We finally employ the meta-model approach to study the impact of the higher-order contributions on the neutron-star crust-core transition density, and find a small 5\% correction.
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