{"title":"12C 结构和反应的详细研究","authors":"Lorenzo Fortunato","doi":"10.1007/s00601-023-01870-5","DOIUrl":null,"url":null,"abstract":"<div><p>We are reporting here on a series of theoretical investigations with both algebraic models and geometric cluster models of alpha clusters in <span>\\(^{12}\\)</span>C, focusing on the structure of the ground state, the first excited <span>\\(0^+\\)</span> state and the second excited <span>\\(2^+\\)</span> state with the purpose, in particular, of establishing if the rotational bands are compatible with rigid structures or rather if they are quantum mixture of different configurations. In a first series of paper (Vitturi et al., Transition densities and form factors in the triangular <span>\\(\\alpha \\)</span>-cluster model of 12C with application to 12C+<span>\\(\\alpha \\)</span> scattering. Phys Rev C 101:014315, 2020; Casal et al., Alpha-induced inelastic scattering and alpha-transfer reactions in 12C and 16O within the Algebraic Cluster Model. Eur Phys J A 57:33, 2021), we assume a rigid equilateral triangle shape and study in detail several properties that descend from the algebraic framework, such as the energy spectrum, electromagnetic observables and calculate the transition densities in order to extract elastic and inelastic cross-sections for various processes. In a second series of papers (Moriya et al., Three-<span>\\(\\alpha \\)</span> Configurations in the 0<span>\\(^+\\)</span> States of 12C. Few-Body Syst 62:46, 2021; Moriya et al., Three-<span>\\(\\alpha \\)</span> configurations of the second <span>\\(J^\\pi \\)</span> = 0<span>\\(^+\\)</span> state in 12C. Eur. Phys J A 59:37, 2023), we solve the three-body Schrödinger equation with orthogonality conditions using the stochastic variational method with correlated Gaussian basis functions. The two-body density distributions indicate that the main configurations of both the <span>\\(0_2^+\\)</span> and <span>\\(2_2^+\\)</span> states are acute iscosceles triangle shapes coming from <span>\\(^8\\)</span>Be(<span>\\(0^+\\)</span>)+<span>\\(\\alpha \\)</span> configurations and find some hints that the second <span>\\(2^+\\)</span> state is not an ideal rigid rotational band member of the Hoyle state band.</p></div>","PeriodicalId":556,"journal":{"name":"Few-Body Systems","volume":null,"pages":null},"PeriodicalIF":1.7000,"publicationDate":"2023-12-05","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Detailed Studies of 12C Structure and Reactions\",\"authors\":\"Lorenzo Fortunato\",\"doi\":\"10.1007/s00601-023-01870-5\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>We are reporting here on a series of theoretical investigations with both algebraic models and geometric cluster models of alpha clusters in <span>\\\\(^{12}\\\\)</span>C, focusing on the structure of the ground state, the first excited <span>\\\\(0^+\\\\)</span> state and the second excited <span>\\\\(2^+\\\\)</span> state with the purpose, in particular, of establishing if the rotational bands are compatible with rigid structures or rather if they are quantum mixture of different configurations. In a first series of paper (Vitturi et al., Transition densities and form factors in the triangular <span>\\\\(\\\\alpha \\\\)</span>-cluster model of 12C with application to 12C+<span>\\\\(\\\\alpha \\\\)</span> scattering. Phys Rev C 101:014315, 2020; Casal et al., Alpha-induced inelastic scattering and alpha-transfer reactions in 12C and 16O within the Algebraic Cluster Model. Eur Phys J A 57:33, 2021), we assume a rigid equilateral triangle shape and study in detail several properties that descend from the algebraic framework, such as the energy spectrum, electromagnetic observables and calculate the transition densities in order to extract elastic and inelastic cross-sections for various processes. In a second series of papers (Moriya et al., Three-<span>\\\\(\\\\alpha \\\\)</span> Configurations in the 0<span>\\\\(^+\\\\)</span> States of 12C. Few-Body Syst 62:46, 2021; Moriya et al., Three-<span>\\\\(\\\\alpha \\\\)</span> configurations of the second <span>\\\\(J^\\\\pi \\\\)</span> = 0<span>\\\\(^+\\\\)</span> state in 12C. Eur. Phys J A 59:37, 2023), we solve the three-body Schrödinger equation with orthogonality conditions using the stochastic variational method with correlated Gaussian basis functions. 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引用次数: 0
摘要
我们在这里报告的是(^{12}\)C 中α簇的代数模型和几何簇模型的一系列理论研究,重点是基态、第一激发态和第二激发态的结构,特别是为了确定旋转带是否与刚性结构兼容,或者它们是否是不同构型的量子混合物。在第一组论文(维图里等人,《12C三角簇模型中的转变密度和形式因子在12C+\(α\)散射中的应用》。Phys Rev C 101:014315, 2020; Casal et al., Alpha-induced inelastic scattering and alpha-transfer reactions in 12C and 16O within the Algebraic Cluster Model.Eur Phys J A 57:33, 2021)中,我们假设了一个刚性等边三角形形状,并详细研究了代数框架的若干属性,如能谱、电磁观测值,并计算了过渡密度,以提取各种过程的弹性和非弹性截面。在第二个系列的论文(Moriya 等,Three-\(α \) Configurations in the 0\(^+\) States of 12C.Few-Body Syst 62:46, 2021; Moriya et al., Three-\(\alpha \) configurations of the second \(J^\pi \) = 0\(^+\) state in 12C.Eur.Phys J A 59:37, 2023),我们使用具有相关高斯基函数的随机变分法求解了具有正交条件的三体薛定谔方程。二体密度分布表明,\(0_2^+\)态和\(2_2^+\)态的主要构型都是\(^8\)Be(\(0^+\))+\(α\)构型的锐角等腰三角形,并发现了一些暗示,即第二个\(2^+\)态并不是霍伊尔态带的理想刚性旋转带成员。
We are reporting here on a series of theoretical investigations with both algebraic models and geometric cluster models of alpha clusters in \(^{12}\)C, focusing on the structure of the ground state, the first excited \(0^+\) state and the second excited \(2^+\) state with the purpose, in particular, of establishing if the rotational bands are compatible with rigid structures or rather if they are quantum mixture of different configurations. In a first series of paper (Vitturi et al., Transition densities and form factors in the triangular \(\alpha \)-cluster model of 12C with application to 12C+\(\alpha \) scattering. Phys Rev C 101:014315, 2020; Casal et al., Alpha-induced inelastic scattering and alpha-transfer reactions in 12C and 16O within the Algebraic Cluster Model. Eur Phys J A 57:33, 2021), we assume a rigid equilateral triangle shape and study in detail several properties that descend from the algebraic framework, such as the energy spectrum, electromagnetic observables and calculate the transition densities in order to extract elastic and inelastic cross-sections for various processes. In a second series of papers (Moriya et al., Three-\(\alpha \) Configurations in the 0\(^+\) States of 12C. Few-Body Syst 62:46, 2021; Moriya et al., Three-\(\alpha \) configurations of the second \(J^\pi \) = 0\(^+\) state in 12C. Eur. Phys J A 59:37, 2023), we solve the three-body Schrödinger equation with orthogonality conditions using the stochastic variational method with correlated Gaussian basis functions. The two-body density distributions indicate that the main configurations of both the \(0_2^+\) and \(2_2^+\) states are acute iscosceles triangle shapes coming from \(^8\)Be(\(0^+\))+\(\alpha \) configurations and find some hints that the second \(2^+\) state is not an ideal rigid rotational band member of the Hoyle state band.
期刊介绍:
The journal Few-Body Systems presents original research work – experimental, theoretical and computational – investigating the behavior of any classical or quantum system consisting of a small number of well-defined constituent structures. The focus is on the research methods, properties, and results characteristic of few-body systems. Examples of few-body systems range from few-quark states, light nuclear and hadronic systems; few-electron atomic systems and small molecules; and specific systems in condensed matter and surface physics (such as quantum dots and highly correlated trapped systems), up to and including large-scale celestial structures.
Systems for which an equivalent one-body description is available or can be designed, and large systems for which specific many-body methods are needed are outside the scope of the journal.
The journal is devoted to the publication of all aspects of few-body systems research and applications. While concentrating on few-body systems well-suited to rigorous solutions, the journal also encourages interdisciplinary contributions that foster common approaches and insights, introduce and benchmark the use of novel tools (e.g. machine learning) and develop relevant applications (e.g. few-body aspects in quantum technologies).