Pairing phase transition in an odd-even hot 69Zn nucleus

IF 3.4 3区物理与天体物理 Q2 PHYSICS, NUCLEAR Journal of Physics G: Nuclear and Particle Physics Pub Date : 2023-05-05 DOI:10.1088/1361-6471/acd2f1

Enakshi Senapati, Satabdi Mondal, S. Bhattacharya, D. Pandit, Nguyen Dinh Dang, N. N. Anh, L. T. Quynh Huong, R. Santra, N. Q. Hưng, B. Dey

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Abstract

The pairing phase transition in an odd-even hot-rotating 69Zn nucleus has been investigated by using the reported nuclear level density (NLD) data, which were experimentally extracted from the γ-gated particle spectra. The experimental NLDs have been compared with those obtained within the microscopic exact pairing plus independent-particle model at finite temperature (EP+IPM) along with the results of other microscopic calculations such as the Hartree-Fock BCS (HFBCS) and Hartree-Fock-Bogoliubov plus combinational (HFBC) methods. It is found that the experimental NLDs can be well described by the EP+IPM using the recommended quadrupole deformation parameter β2 = -0.164. Intriguingly, the heat capacity calculated using the EP+IPM NLD exhibits a sharp S-shape, which is not expected in such odd-even hot or hot-rotating system as reported earlier. Changing the deformation parameter β2 does not change much this S-shape. However, increasing or decreasing the pairing gaps could enhance or destroy the S-shaped heat capacity. Therefore, the S-shaped heat capacity in odd-even 69Zn nucleus is explained due to the deformation induced pairing correlation.

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奇偶热69Zn核中的配对相变

利用从γ门控粒子谱中实验提取的核能级密度(NLD)数据，研究了奇偶热旋转69Zn核中的配对相变。实验NLDs与有限温度下微观精确配对+独立粒子模型(EP+IPM)的结果以及其他微观计算方法(如Hartree-Fock BCS (HFBCS)和Hartree-Fock- bogoliubov +组合(HFBC)方法)的结果进行了比较。采用推荐的四极变形参数β2 = -0.164，用EP+IPM可以很好地描述实验nld。有趣的是，使用EP+IPM NLD计算的热容量显示出一个尖锐的s形，这在之前报道的奇偶热或热旋转系统中是不可能的。改变变形参数β2对s形的影响不大。然而，增大或减小配对间隙可以增强或破坏s型热容。因此，由变形引起的配对相关可以解释69Zn奇偶核的s形热容。

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

Journal of Physics G: Nuclear and Particle Physics 物理-物理：核物理

CiteScore

7.60

自引率

5.70%

发文量

105

审稿时长

1 months

期刊介绍： Journal of Physics G: Nuclear and Particle Physics (JPhysG) publishes articles on theoretical and experimental topics in all areas of nuclear and particle physics, including nuclear and particle astrophysics. The journal welcomes submissions from any interface area between these fields. All aspects of fundamental nuclear physics research, including: nuclear forces and few-body systems; nuclear structure and nuclear reactions; rare decays and fundamental symmetries; hadronic physics, lattice QCD; heavy-ion physics; hot and dense matter, QCD phase diagram. All aspects of elementary particle physics research, including: high-energy particle physics; neutrino physics; phenomenology and theory; beyond standard model physics; electroweak interactions; fundamental symmetries. All aspects of nuclear and particle astrophysics including: nuclear physics of stars and stellar explosions; nucleosynthesis; nuclear equation of state; astrophysical neutrino physics; cosmic rays; dark matter. JPhysG publishes a variety of article types for the community. As well as high-quality research papers, this includes our prestigious topical review series, focus issues, and the rapid publication of letters.