Multiple-models prediction for light neutron-rich isotopes cross section by $Q_g$ systematics in $^{40}$Ar projectile fragmentation reactions

arXiv - PHYS - Nuclear Theory Pub Date : 2024-09-14 DOI:arxiv-2409.09367

X. B. Wei, H. L. Wei, C. W. Ma, C. Y. Qiao, Y. F. Guo, J. Pu, K. X. Cheng, Y. T. Wang, Z. X. Wang, T. R. Zhou, D. Peng, S. T. Wang, S. W. Tang, Y. H. Yu, X. H. Zhang, Y. Z. Sun, S. Y. Jin, G. L. Zhang, X. Jiang, Z. Y. Li, Y. F. Xu, F. H. Lu, T. Q. Liu

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Abstract

Precise predictions for nuclei near drip lines are crucial for experiments in new generation of rare isotope facilities. A multi-models investigation of the $Q_g$ systematics for fragments production cross sections, with $Q_g$ defined as the difference of mass excess (ME) between the projectile ($Z_{p}, A_{p}$) and the fragment ($Z_{f}, A_{f}$) nuclei $Q_{g}=ME(Z_{p}, A_{p})-ME(Z_{f}, A_{f})$, has been performed to verify the model prediction abilities for light neutron-rich isotopes in measured $^{40}$Ar + $^9$Be projectile fragmentation reactions from 57$A$ MeV to 1$A$ GeV. The models used are the FRACS parametrizations and the newly developed Bayesian neural networks (BNN) model. %method The results show that FRACS, BNN, and $Q_g$ extrapolations are generally consistent, except for fragments near the nuclear mass of the projectile. Additionally, both measured data and model extrapolations provide evidence for a shell closure at $N=$ 16 in fluorine and neon, as well as the disappearance of the traditional magic number $N=$ 20 in neon, sodium and magnesium.

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^{40}$Ar射弹碎裂反应中Q_g$系统学对轻中子富同位素截面的多模型预测

对滴流线附近的原子核进行精确预测对于新一代稀有同位素设施的实验至关重要。Q_g$定义为射弹（$Z_{p}, A_{p}$）和碎片（$Z_{f}、Q_{g}=ME(Z_{p}, A_{p})-ME(Z_{f},A_{f})$，以验证模型对从 57$A$ MeV 到 1$A$ GeV 的 $^{40}$Ar + $^9$Be 射弹碎裂反应中富轻中子同位素的预测能力。使用的模型是 FRACSparametrizations 和新开发的贝叶斯神经网络（BNN）模型。此外，测量数据和模型推断都为氟和氖在 $N=$ 16 时的壳关闭以及氖、钠和镁中传统神奇数字 $N=$ 20 的消失提供了证据。

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arXiv - PHYS - Nuclear Theory

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