Impact of correlations on nuclear binding energies

IF 2.6 3区物理与天体物理 Q2 PHYSICS, NUCLEAR The European Physical Journal A Pub Date : 2024-10-21 DOI:10.1140/epja/s10050-024-01424-1

A. Scalesi, T. Duguet, P. Demol, M. Frosini, V. Somà, A. Tichai

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Abstract

A strong effort will be dedicated in the coming years to extend the reach of ab initio nuclear-structure calculations to heavy doubly open-shell nuclei. In order to do so, the most efficient strategies to incorporate dominant many-body correlations at play in such nuclei must be identified. With this motivation in mind, the present work analyses the step-by-step inclusion of many-body correlations and their impact on binding energies of Calcium and Chromium isotopes. Employing an empirically-optimal Hamiltonian built from chiral effective field theory, binding energies along both isotopic chains are studied via a hierarchy of approximations based on polynomially-scaling expansion many-body methods. More specifically, calculations are performed based on (i) the spherical Hartree–Fock–Bogoliubov mean-field approximation plus correlations from second-order Bogoliubov many-body perturbation theory or Bogoliubov coupled cluster with singles and doubles on top of it, along with (ii) the axially-deformed Hartree–Fock–Bogoliubov mean-field approximation plus correlations from second-order Bogoliubov many-body perturbation theory built on it. The corresponding results are compared to experimental data and to those obtained via valence-space in-medium similarity renormalization group calculations at the normal-ordered two-body level that act as a reference in the present study. The spherical mean-field approximation is shown to display specific shortcomings in Ca isotopes that can be understood analytically and that are efficiently corrected via the consistent addition of low-order dynamical correlations on top of it. While the same setting cannot appropriately reproduce binding energies in doubly open-shell Cr isotopes, allowing the unperturbed mean-field state to break rotational symmetry permits to efficiently capture the static correlations responsible for the phenomenological differences observed between the two isotopic chains. Eventually, the present work demonstrates that polynomially-scaling expansion methods based on unperturbed states that possibly break (and restore) symmetries constitute an optimal route to extend ab initio calculations to heavy closed- and open-shell nuclei.

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相关性对核结合能的影响

在未来几年里，我们将致力于把原子核结构计算的范围扩大到重型双开壳原子核。为此，必须找出最有效的策略，以纳入在这类原子核中起作用的主要多体相关性。基于这一动机，本研究分析了逐步纳入多体相关性及其对钙和铬同位素结合能的影响。利用手性有效场理论建立的经验最优哈密顿，通过基于多项式缩放扩展多体方法的近似层次，研究了两条同位素链的结合能。更具体地说，计算基于 (i) 球形哈特里-福克-波哥柳波夫均场近似，加上二阶波哥柳波夫多体扰动理论或波哥柳波夫耦合簇的单体和双体相关性，以及 (ii) 轴向变形哈特里-福克-波哥柳波夫均场近似，加上在此基础上建立的二阶波哥柳波夫多体扰动理论的相关性。相应的结果与实验数据以及在本研究中作为参考的正序二体水平上通过价空间中相似重正化群计算得到的结果进行了比较。球面均场近似在钙同位素中显示出特定的缺陷，这些缺陷可以通过分析理解，并通过在其基础上持续添加低阶动力学相关性得到有效修正。虽然同样的设置无法恰当地再现双开壳铬同位素的结合能，但允许未扰动均场状态打破旋转对称性，可以有效地捕捉到静态相关性，这种静态相关性造成了在两种同位素链之间观察到的现象学差异。最终，本研究表明，基于可能打破（和恢复）对称性的未扰动态的多项式缩放扩展方法，是将原子核的非线性计算扩展到重型闭壳和开壳原子核的最佳途径。

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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.