手性有效场论与核结合中的功率计数

C.-J. Yang, A. Ekström, C. Forss'en, G. Hagen
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引用次数: 6

摘要

Weinberg最初提出的手性有效场论($\chi$ EFT)保证了低能核相互作用与量子色动力学(QCD)之间的理论联系。然而,重整化群(RG)不变性的重要性质在目前的实现中尚未实现,其对预测二核子和三核子系统以外的原子核的影响仍然未知。在这项工作中,我们首次系统地研究了最近的$\chi$ EFT的rg不变公式,以及它们对质量数高达$A =16$的选定核系统的结合能和其他观测值的预测。具体地说,我们使用几种最近的功率计数(PC)方案在领先级(LO)和次领先级(NLO)上进行了从头开始的无核壳模型和耦合簇计算$^3$ H, $^{3,4}$ He, $^{6}$ Li和$^{16}$ O的基态能量,其中次领先相互作用在微扰理论中进行了处理。我们的计算表明,对于质量数为$A \leq 4$的原子核,可以得到rg不变和现实的预测。然而,我们发现$^{16}$ O相对于四个$\alpha$ -粒子阈值要么是不受约束的,要么是变形的,要么两者兼而有之。同样地,我们发现$^{6}$ Li基态位于$\alpha$ -氘核分离阈值之上。这些结果与实验数据形成鲜明对比,并指出要么对所有相关反项进行必要的微调,要么在$\chi$ EFT中LO当前最先进的rg不变PC方案缺乏必要的图表-例如三核子力-以实际描述质量数$A>4$的原子核。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Power counting in chiral effective field theory and nuclear binding
Chiral effective field theory ($\chi$EFT), as originally proposed by Weinberg, promises a theoretical connection between low-energy nuclear interactions and quantum chromodynamics (QCD). However, the important property of renormalization-group (RG) invariance is not fulfilled in current implementations and its consequences for predicting atomic nuclei beyond two- and three-nucleon systems has remained unknown. In this work we present a first and systematic study of recent RG-invariant formulations of $\chi$EFT and their predictions for the binding energies and other observables of selected nuclear systems with mass-numbers up to $A =16$. Specifically, we have carried out ab initio no-core shell-model and coupled cluster calculations of the ground-state energy of $^3$H, $^{3,4}$He, $^{6}$Li, and $^{16}$O using several recent power-counting (PC) schemes at leading order (LO) and next-to-leading order (NLO), where the subleading interactions are treated in perturbation theory. Our calculations indicate that RG-invariant and realistic predictions can be obtained for nuclei with mass number $A \leq 4$. We find, however, that $^{16}$O is either unbound with respect to the four $\alpha$-particle threshold, or deformed, or both. Similarly, we find that the $^{6}$Li ground-state resides above the $\alpha$-deuteron separation threshold. These results are in stark contrast with experimental data and point to either necessary fine-tuning of all relevant counterterms, or that current state-of-the-art RG-invariant PC schemes at LO in $\chi$EFT lack necessary diagrams -- such as three-nucleon forces -- to realistically describe nuclei with mass number $A>4$.
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