2019
DOI: 10.1103/physrevc.99.034605
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Microscopic global optical potential for nucleon-nucleus systems in the energy range 50–400 MeV

Abstract: We provide a microscopic global optical potential (MGOP) for nucleon-nucleus (NA) systems in a wide range of nuclear mass numbers (A = 10-276) and incident energies (E = 50-400 MeV). The potential is microscopically constructed based on a single-folding (SF) model with the complex G-matrix interaction. The nuclear densities used in the SF model are generated, in a nonempirical way, from two kinds of microscopic mean-field models: the relativistic-mean-field (RMF) and Skyrme-Hartree-Fock + BCS (HF+BCS) models. … Show more

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Cited by 35 publications
(16 citation statements)
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References 207 publications
(302 reference statements)
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“…Historically, two cornerstone frameworks have been employed. First, few-body techniques (with early applications to reactions) use correct asymptotics (i.e., the wave function of the reaction fragments at long distances), but may often neglect the microscopic structure of the clusters and employ optical potentials fitted to elastic scattering data of stable nuclei (e.g., [64][65][66]. Second, many-body techniques (with early applications to structure) use many-body degrees of freedom and target unified structure and reaction descriptions, but may often neglect or only partially account for the continuum, and are often limited in mass or number of active particles as a result of increased complexity.…”
Section: Rare Isotope Beam Facilities and The Need For Theorymentioning
confidence: 99%
“…Historically, two cornerstone frameworks have been employed. First, few-body techniques (with early applications to reactions) use correct asymptotics (i.e., the wave function of the reaction fragments at long distances), but may often neglect the microscopic structure of the clusters and employ optical potentials fitted to elastic scattering data of stable nuclei (e.g., [64][65][66]. Second, many-body techniques (with early applications to structure) use many-body degrees of freedom and target unified structure and reaction descriptions, but may often neglect or only partially account for the continuum, and are often limited in mass or number of active particles as a result of increased complexity.…”
Section: Rare Isotope Beam Facilities and The Need For Theorymentioning
confidence: 99%
“…Experiments at current and upcoming rare isotope beam facilities can probe nucleon-nucleon interactions and nuclear structure, but require novel theoretical approaches that can reliably model reactions of shortlived isotopes to support and inform experimental programs. Historically, two major cornerstone frameworks have been developed: (1) Few-body techniques (with early applications to reactions) use correct asymptotics (i.e., the wave function of the reaction fragments at large distances), but may often neglect the microscopic structure of the clusters and employ optical potentials fitted to elastic scattering data of stable nuclei (see, e.g., 65,66,67). (2) Many-body techniques (with early applications to structure) use many-body degrees of freedom and target unified structure and reaction descriptions, but may often neglect or partially account for the continuum and are often limited in mass or number of active particles, as a result of increased complexity.…”
Section: Rare Isotope Beam Facilities and Needs For Theorymentioning
confidence: 99%
“…We applied the calculated transition densities to MCC calculations with the complex G-matrix interaction MPa [55,56]. The MPa interaction has been proven to be successful in nuclear reactions [42,50,57,58]. As a detailed calculation procedure for the folding potential has been described in previous researches [39,50,59], herein, only the essence of the MCC calculation was briefly introduced.…”
Section: B MCC Modelmentioning
confidence: 99%
“…Since the complex G-matrix is constructed in the infinite nuclear matter, the strength of the imaginary part is often adjusted in the use for the finite nucleus because these level densities are quite different. Therefore, we take the incident-energy-dependent renormalization factor, N W = 0.5 + (E/A)/1000 [58], for the imaginary part of the folding model potential.…”
Section: B MCC Modelmentioning
confidence: 99%