Entrance channel-dependent compound nucleus formation probability of heavy nuclei

IF 1.9 4区物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY

Pramana Pub Date : 2025-03-19 DOI:10.1007/s12043-025-02900-z

H S Anushree, S Shubha, H C Manjunatha, N Sowmya

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引用次数: 0

Abstract

Compound nucleus (CN) formation probability (\(P_{\textrm{CN}}\)) is essential for synthesising superheavy elements (SHEs), understanding nuclear reactions, predicting reaction outcomes and designing efficient experiments. High \(P_{\textrm{CN}}\) indicates a greater likelihood of successful fusion, aiding in the study of nuclear stability and structure. An empirical formula for \(P_{\textrm{CN}}\) has been proposed, incorporating new parameters such as effective fissility (\(\chi _{\textrm{eff}}\)) and zeta parameter (\(\zeta \)), along with excitation energy and fusion barrier height. The fitted function shows greater systematic behaviour for \((E^*-V_B)\chi _{\textrm{eff}}\) and \(\zeta ^{0.02}\). \(P_{\textrm{CN}}\) values obtained align well with the experimental data, predicting outcomes for both successful and unsuccessful fusion reactions. Notably, larger \(P_{\textrm{CN}}\) values are seen for \(\phantom {a}^{45}\hbox {Sc}{+}^{249}\hbox {Cf}\) and \(\phantom {a}^{50}\hbox {Ti}{+}^{249}\hbox {Bk}\) for \(Z=119\) and 120, respectively. Analysis identifies \(\phantom {a}^{80}\hbox {Se}{+}^{210}\hbox {At}\) and \(\phantom {a}^{55}\hbox {Mn}{+}^{241}\hbox {Pu}\) as potential reactions for synthesising the SHE (\(Z=119\)), with Mn projectiles showing higher \(P_{\textrm{CN}}\) than Se projectiles due to lower \(\zeta \) and deformation effects. Hence, \(\phantom {a}^{55}\hbox {Mn}{+}^{241}\hbox {Pu}\) is more promising than \(\phantom {a}^{80}\hbox {Se}{+}^{210}\hbox {At}\) for this purpose. The present work is useful for focussing experimental efforts and increasing the efficiency of SHE research by focussing on reactions with higher CN formation probability.

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依赖入口通道的重核复合核形成概率

复合核（CN）形成概率（\(P_{\textrm{CN}}\)）是合成超重元素（SHEs）、理解核反应、预测反应结果和设计有效实验的必要条件。\(P_{\textrm{CN}}\)值越高，表明核聚变成功的可能性越大，有助于研究核的稳定性和结构。本文提出了一个\(P_{\textrm{CN}}\)的经验公式，加入了新的参数，如有效裂变率（\(\chi _{\textrm{eff}}\)）和zeta参数（\(\zeta \)），以及激发能和聚变势垒高度。拟合的函数对\((E^*-V_B)\chi _{\textrm{eff}}\)和\(\zeta ^{0.02}\)表现出更大的系统行为。获得的\(P_{\textrm{CN}}\)值与实验数据很好地吻合，预测了成功和不成功聚变反应的结果。值得注意的是，对于\(\phantom {a}^{45}\hbox {Sc}{+}^{249}\hbox {Cf}\)和\(\phantom {a}^{50}\hbox {Ti}{+}^{249}\hbox {Bk}\)，分别可以看到较大的\(P_{\textrm{CN}}\)值，对于\(Z=119\)和120。分析确定\(\phantom {a}^{80}\hbox {Se}{+}^{210}\hbox {At}\)和\(\phantom {a}^{55}\hbox {Mn}{+}^{241}\hbox {Pu}\)是合成SHE （\(Z=119\)）的潜在反应，由于\(\zeta \)和变形效应较低，Mn射弹的\(P_{\textrm{CN}}\)比Se射弹高。因此，对于这个目的，\(\phantom {a}^{55}\hbox {Mn}{+}^{241}\hbox {Pu}\)比\(\phantom {a}^{80}\hbox {Se}{+}^{210}\hbox {At}\)更有希望。本文的工作有助于集中实验工作，通过关注具有较高CN形成概率的反应来提高SHE研究的效率。

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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来源期刊

Pramana 物理-物理：综合

CiteScore

3.60

自引率

7.10%

发文量

206

审稿时长

3 months

期刊介绍： Pramana - Journal of Physics is a monthly research journal in English published by the Indian Academy of Sciences in collaboration with Indian National Science Academy and Indian Physics Association. The journal publishes refereed papers covering current research in Physics, both original contributions - research papers, brief reports or rapid communications - and invited reviews. Pramana also publishes special issues devoted to advances in specific areas of Physics and proceedings of select high quality conferences.