University of the West of Scotland Nuclear Physics Group Consolidated Grant

西苏格兰大学核物理组综合拨款

• 批准号: ST/V001124/1
• 负责人: John Smith
• 金额: $ 62.66万
• 依托单位: University of the West of Scotland
• 依托单位国家: 英国
• 项目类别: Research Grant
• 财政年份: 2021
• 资助国家: 英国
• 起止时间: 2021 至 无数据
• 项目状态: 未结题
• 来源: https://gtr.ukri.org/projects?ref=ST%2FV001124%2F1
• 关键词: University; West; Scotland; Nuclear; Physics

More than a century since Rutherford identified the atomic nucleus in alpha-particle scattering experiments in Manchester, the science of nuclear physics remains vibrant and active. Over the past 100 years, there has been a wealth of experimental and theoretical research that has led to milestone results and discoveries, such as the discovery of the neutron, the development of successful models of the nucleus, and the identification of numerous novel decay modes. Progress in nuclear physics has gone hand-in-hand with the development of particle accelerators, which started with modest electrostatic machines, capable of accelerating light ions, and resulting in modern day accelerators capable of accelerating any nucleus up to uranium-238, with energies of 10 MeV per nucleon or more. Facilities now exist that can accelerate radioactive ions, and there is effort being put into improving the intensities, energies, and purity of radioactive beams. Despite the wealth of research activity in nuclear physics, and the maturity of the subject, a complete understanding of the atomic nucleus has still not been achieved. There are still many open questions that need to be answered, which we will address is our research programme. Also, technological and scientific developments in nuclear physics are leading to applications outside of the areas of fundamental science - nuclear-related concepts are now used in many areas of industry and medicine, leading to additional areas of research. Our programme of research in this Consolidated Grant application covers research into the structure, behaviour and properties of atomic nuclei that lie far from stability as well as collective behaviour in stable nuclei, which remains poorly understood. One of the main parts of our programme of research is the study of the shapes of atomic nuclei. It is well established that nuclei with filled shells of neutrons and protons are spherical, and nuclei with partially-filled shells can become deformed. One of the themes within our research programme will study quadrupole shaped nuclei, where the nucleus takes on a rugby-ball shape. This type of nuclear deformation is prevalent and occurs in many different regions of the nuclear chart. A more exotic form of deformation is when the nucleus takes on a reflection-asymmetric "pear" shape. Such octupole deformation is most prominent in localized regions of the nuclear chart, such as the light actinide region (radium, thorium, uranium nuclei with A~224) and lanthanides near barium-144. In our research programme, we will make a comprehensive study of octupole deformation in nuclei, focusing on the actinide and lanthanide regions, as well as the proton-rich nuclei near N=Z=56. Interestingly, atoms containing pear-shaped nuclei are excellent candidates in which to search for matter-antimatter symmetry violating physics.Over the past 20 years, experimental observations, supported by theoretical calculations, have suggested that the structure of exotic nuclei may be different from those near stability. The well-known sequence of magic numbers, corresponding to energy gaps in nuclear shell structure, is now thought to change in nuclei that lie far from stability. In our programme, we will study the shell structure in a range of nuclei across the nuclear chart, including the nuclei close to the doubly-magic nuclei Sn-100 and Pb-208. Another aspect of our research programme is a study of high-energy collective modes in nuclei, in novel experiments induced by beams of gamma rays. In addition, a new aspect to our research is a study of reactions relevant to nuclear astrophysics, which will include a focus on hydrogen burning that occurs in stars.

自卢瑟福在曼彻斯特的α粒子散射实验中确定原子核以来的世纪多，核物理科学仍然充满活力和活跃。在过去的100年里，有大量的实验和理论研究，导致了里程碑式的结果和发现，如中子的发现，核的成功模型的发展，以及许多新的衰变模式的识别。核物理学的进步与粒子加速器的发展齐头并进，粒子加速器始于能够加速轻离子的普通静电机器，并导致现代加速器能够加速任何核，直到铀-238，每个核子的能量为10 MeV或更高。现在已经有了可以加速放射性离子的设施，人们正在努力提高放射性束的强度、能量和纯度。尽管核物理学的研究活动非常丰富，而且学科也已经成熟，但人们仍然没有完全理解原子核。仍然有许多悬而未决的问题需要回答，我们将解决的是我们的研究计划。此外，核物理学的技术和科学发展正在导致基础科学领域以外的应用-与核有关的概念现在被用于工业和医学的许多领域，从而导致更多的研究领域。我们在这个综合资助申请的研究方案涵盖了对原子核的结构，行为和性质的研究，这些原子核远离稳定性以及稳定核中的集体行为，这仍然知之甚少。我们研究计划的主要部分之一是研究原子核的形状。众所周知，具有中子和质子填充壳层的核是球形的，并且具有部分填充壳层的核可以变形。我们的研究计划中的一个主题将研究四极形状的原子核，其中原子核呈现橄榄球形状。这种类型的核变形是普遍的，发生在核图的许多不同区域。更奇特的变形形式是原子核呈现出反射不对称的“梨”形。这种八极形变在原子核图的局部区域最为突出，例如轻锕系元素区域（镭、钍、铀核，A~224）和钡-144附近的镧系元素。在我们的研究计划中，我们将对原子核中的八极形变进行全面研究，重点是锕系和镧系区域，以及N=Z=56附近的富质子核。有趣的是，含有梨形核的原子是寻找违反物理学的物质-反物质对称性的最佳候选者。在过去的20年里，实验观察和理论计算都表明，奇异核的结构可能不同于那些接近稳定的核。众所周知的幻数序列，对应于核壳层结构中的能隙，现在被认为在远离稳定的核中会发生变化。在我们的计划中，我们将研究核图表中一系列核的壳结构，包括接近双幻核Sn-100和Pb-208的核。我们的研究计划的另一个方面是在伽马射线束引起的新实验中研究原子核中的高能集体模式。此外，我们研究的一个新方面是研究与核天体物理学有关的反应，其中将包括关注恒星中发生的氢燃烧。

项目成果

Photo-response of the $$N=Z$$ nucleus $$^{24}$$Mg

$$N=Z$$ 核的光响应 $$^{24}$$Mg

• DOI: 10.1140/epja/s10050-023-01111-7
• 发表时间: 2023
• 期刊: The European Physical Journal A
• 作者: Deary J

Spectroscopic studies of neutron-rich In 129 and its ß -decay daughter, Sn 129 , using the GRIFFIN spectrometer

使用 GRIFFIN 光谱仪对富中子 In 129 及其衰变子体 Sn 129 进行光谱研究

• DOI: 10.1103/physrevc.103.024310
• 发表时间: 2021
• 期刊: Physical Review C
• 影响因子: 3.1
• 作者: Garcia F

Decay spectroscopy at the two-proton drip line: Radioactivity of the new nuclides 160Os and 156W

双质子滴注线的衰变光谱：新核素 160Os 和 156W 的放射性

• DOI: 10.1016/j.physletb.2023.138310
• 发表时间: 2023
• 期刊: Physics Letters B
• 影响因子: 4.4
• 作者: Briscoe A

Abrasion-fission reactions at intermediate energies

• DOI: 10.1103/physrevc.108.034604
• 发表时间: 2023-09
• 期刊: Physical Review C
• 影响因子: 3.1
• 作者: M. Bowry;O. Tarasov;J. Berryman;V. Bader;Dominique Bazin;T. Chupp;H. Crawford;A. Gade;E. Lunderberg;A. Ratkiewicz;F. Recchia;B. Sherrill;D. Smalley;A. Stolz;Steven Ragnar Stroberg;D. Weisshaar;S. Williams;K. Wimmer;J. Yurkon

Decay spectroscopy of Sc 50 and Sc 50 m to Ti 50

Sc 50 和 Sc 50 m 到 Ti 50 的衰变光谱

• DOI: 10.1103/physrevc.104.024314
• 发表时间: 2021
• 期刊: Physical Review C
• 影响因子: 3.1
• 作者: Bowry M