Three-body structure of B19 : Finite-range effects in two-neutron halo nuclei

J. Casal, E. Garrido
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引用次数: 2

Abstract

The structure and $B(E1)$ transition strength of $^{19}$B are investigated in a $^{17}\text{B}+n+n$ model, triggered by a recent experiment showing that $^{19}$B exhibits a well pronounced two-neutron halo structure. Preliminary analysis of the experimental data were made by employing contact $n$-$n$ interactions, which are known to underestimate the $s$-wave content in other halo nuclei such as $^{11}$Li. In the present work, the three-body hyperspherical formalism with finite-range two-body interactions is used to describe $^{19}$B. In particular, two different finite range $n$-$n$ interactions will be used, as well as a simple central Gaussian potential whose range is progressively reduced. The purpose is to determine the main properties of the nucleus and investigate how they change when using contact-like $n$-$n$ potentials. Special attention is also paid to the dependence on the prescription used to account for three-body effects, i.e., a three-body force or a density-dependent $n$-$n$ potential. We have found that the three-body model plus finite range potentials provide a description of $^{19}$B consistent with the experimental data. The results are essentially independent of the short-distance details of the two-body potentials, giving rise to an $(s_{1/2})^2$ content of about 55%, clearly larger than the initial estimates. Very little dependence has been found as well on the prescription used for the three-body effects. The total computed $B(E1)$ strength is compatible with the experimental result, although we slightly overestimate the data around the low-energy peak of the $dB(E1)/d\varepsilon$ distribution. Finally, we show that a reduction of the $n$-$n$ interaction range produces a significant reduction of the $s$-wave contribution, which then should be expected in calculations using contact interactions.
B19的三体结构:双中子晕核的有限范围效应
在$^{19}$B的$^{17}\text{B}+n+n$模型中研究了$^{19}$B的结构和$B(E1)$跃迁强度,该模型是由最近的一个实验触发的,该实验表明$^{19}$B具有明显的双中子晕结构。利用接触n - n相互作用对实验数据进行了初步分析,这种相互作用被认为低估了其他晕核(如Li)中的s波含量。本文采用具有有限范围两体相互作用的三体超球面形式来描述$^{19}$B。特别地,将使用两个不同的有限范围$n$-$n$相互作用,以及一个范围逐渐减小的简单高斯中心势。目的是确定原子核的主要性质,并研究它们在使用类接触n - n势时如何变化。还特别注意对用于解释三体效应的处方的依赖性,即三体力或与密度相关的$n$-$n$势。我们发现三体模型加上有限范围势提供了与实验数据一致的$^{19}$B的描述。结果基本上与两体势的短距离细节无关,从而产生了约55%的$(s_{1/2})^2$含量,明显大于最初的估计。对用于三体效应的处方的依赖也很少。虽然我们稍微高估了$dB(E1)/d\varepsilon$分布的低能峰附近的数据,但计算的$B(E1)$强度与实验结果是一致的。最后,我们表明,$n$-$n$相互作用范围的减小会产生$s$波贡献的显着减少,这在使用接触相互作用的计算中应该是预期的。
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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