核物理和粒子物理中使用的光学模型中的分数微积分

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 : 2022-09-28 DOI:10.1088/1361-6471/acbe58

R. Herrmann

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引用次数: 1

摘要

光学模型是描述核物理散射过程的基本工具。基本输入是光学模型势，它或多或少地示意性地描述了折射和吸收过程。特别令人感兴趣的是吸收势的形式。随着入射射弹能量的增加，该势的推导必须考虑到观察到的从表面到体积类型的能量依赖性转变。传统方法在这方面有弱点。我们将讨论这些不足，并提出一种基于分数微积分框架内发展的概念的替代方法，该方法允许以适当的方式描述从表面吸收到体积吸收的平稳过渡。特别令人感兴趣的是吸收势的形式。随着入射射弹能量的增加，该势的推导必须考虑从假想表面到体积项的能量依赖性转变。我们讨论了经典方法的不足，并提出了一种基于分数微积分框架内发展的概念的替代方法，该方法允许以自然的方式描述从表面吸收到体积吸收的平稳过渡。

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Fractional calculus within the optical model used in nuclear and particle physics

The optical model is a fundamental tool to describe scattering processes in nuclear physics. The basic input is an optical model potential, which describes the refraction and absorption processes more or less schematically. Of special interest is the form of the absorption potential. With increasing energy of the incident projectile, a derivation of this potential must take into account the observed energy dependent transition from surface to volume type. The classic approach has weaknesses in this regard. We will discuss these deficiencies and will propose an alternative method based on concepts developed within the framework of fractional calculus, which allows to describe a smooth transition from surface to volume absorption in an appropriate way. Of special interest is the form of the absorption potential. With increasing energy of the incident projectile, a derivation of this potential must take into account energy dependent transition from imaginary surface to volume terms. We discuss the deficiencies of the classical approach and propose an alternative method based on concepts developed within the framework of fractional calculus, which allows to describe a smooth transition from surface to volume absorption in a natural way.

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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.