Effects of nuclear structure on quasi-fission

Cédric Simenel; Aditya Wakhle; B. Avez; D. J. Hinde; R. Du Rietz; M. Dasgupta; M. Evers; C. J. Lin; D. H. Luong

doi:10.1051/epjconf/20123809001

Effects of nuclear structure on quasi-fission

Cédric Simenel, Aditya Wakhle, B. Avez, D. J. Hinde, R. Du Rietz, M. Dasgupta, M. Evers, C. J. Lin, D. H. Luong

Research output: Contribution to journal › Conference article › peer-review

13 Citations (Scopus)

Abstract

The quasi-fission mechanism hinders fusion of heavy systems because of a mass flow between the reactants, leading to a re-separation of more symmetric fragments in the exit channel. A good understanding of the competition between fusion and quasi-fission mechanisms is expected to be of great help to optimize the formation and study of heavy and superheavy nuclei. Quantum microscopic models, such as the time-dependent Hartree-Fock approach, allow for a treatment of all degrees of freedom associated to the dynamics of each nucleon. This provides a description of the complex reaction mechanisms, such as quasi-fission, with no parameter adjusted on reaction mechanisms. In particular, the role of the deformation and orientation of a heavy target, as well as the entrance channel magicity and isospin are investigated with theoretical and experimental approaches.

Original language	English
Article number	09001
Journal	EPJ Web of Conferences
Volume	38
DOIs	https://doi.org/10.1051/epjconf/20123809001
Publication status	Published - 2012
Event	6th International Conference on Nuclear Structure and Related Topics, NSRT 2012 - Dubna, Russian Federation Duration: 3 Jul 2012 → 7 Jul 2012

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title = "Effects of nuclear structure on quasi-fission",

abstract = "The quasi-fission mechanism hinders fusion of heavy systems because of a mass flow between the reactants, leading to a re-separation of more symmetric fragments in the exit channel. A good understanding of the competition between fusion and quasi-fission mechanisms is expected to be of great help to optimize the formation and study of heavy and superheavy nuclei. Quantum microscopic models, such as the time-dependent Hartree-Fock approach, allow for a treatment of all degrees of freedom associated to the dynamics of each nucleon. This provides a description of the complex reaction mechanisms, such as quasi-fission, with no parameter adjusted on reaction mechanisms. In particular, the role of the deformation and orientation of a heavy target, as well as the entrance channel magicity and isospin are investigated with theoretical and experimental approaches.",

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T1 - Effects of nuclear structure on quasi-fission

AU - Simenel, Cédric

AU - Wakhle, Aditya

AU - Avez, B.

AU - Hinde, D. J.

AU - Du Rietz, R.

AU - Dasgupta, M.

AU - Evers, M.

AU - Lin, C. J.

AU - Luong, D. H.

PY - 2012

Y1 - 2012

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AB - The quasi-fission mechanism hinders fusion of heavy systems because of a mass flow between the reactants, leading to a re-separation of more symmetric fragments in the exit channel. A good understanding of the competition between fusion and quasi-fission mechanisms is expected to be of great help to optimize the formation and study of heavy and superheavy nuclei. Quantum microscopic models, such as the time-dependent Hartree-Fock approach, allow for a treatment of all degrees of freedom associated to the dynamics of each nucleon. This provides a description of the complex reaction mechanisms, such as quasi-fission, with no parameter adjusted on reaction mechanisms. In particular, the role of the deformation and orientation of a heavy target, as well as the entrance channel magicity and isospin are investigated with theoretical and experimental approaches.

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Effects of nuclear structure on quasi-fission

Abstract

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