Emergence of High-Order Deformation in Rotating Transfermium Nuclei: A Microscopic Understanding

arXiv - PHYS - Nuclear Experiment Pub Date : 2024-07-12 DOI:arxiv-2407.08996

F. F. Xu, Y. K. Wang, Y. P. Wang, P. Ring, P. W. Zhao

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Abstract

The rotational properties of the transfermium nuclei are investigated in the full deformation space by implementing a shell-model-like approach in the cranking covariant density functional theory on a three-dimensional lattice, where the pairing correlations, deformations, and moments of inertia are treated in a microscopic and self-consistent way. The kinematic and dynamic moments of inertia of the rotational bands observed in the transfermium nuclei $^{252}$No, $^{254}$No, $^{254}$Rf, and $^{256}$Rf are well reproduced without any adjustable parameters using a well-determined universal density functional. It is found for the first time that the emergence of the octupole deformation should be responsible for the significantly different rotational behavior observed in $^{252}$No and $^{254}$No. The present results provide a microscopic solution to the long-standing puzzle on the rotational behavior in No isotopes, and highlight the risk of investigating only the hexacontetrapole ($\beta_{60}$) deformation effects in rotating transfermium nuclei without considering the octupole deformation.

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旋转铵核中高阶变形的出现：微观理解

通过在三维晶格上的ranking协变密度泛函理论中实施类似壳模型的方法，研究了转移铟核在全变形空间中的旋转特性，其中配对相关性、变形和惯性矩是以微观和自洽的方式处理的。利用一个确定的通用密度函数，在没有任何可调参数的情况下，很好地再现了在转移原子核$^{252}$No、$^{254}$No、$^{254}$Rf和$^{256}$Rf中观察到的旋转带的运动惯性矩和动态惯性矩。研究首次发现，^{252}$No 和 $^{254}$No 中出现的显著不同的旋转行为应归因于八极变形。本研究结果为No同位素旋转行为这一长期存在的谜题提供了一个显微镜下的解决方案，并凸显了在旋转转移铵核中只研究六极（$\beta_{60}$）形变效应而不考虑八极形变的风险。

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arXiv - PHYS - Nuclear Experiment

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