Microscopic description of large amplitude collective motion in the nuclear astrophysics context

Denis Lacroix; Yusuke Tanimura; Guillaume Scamps; Cédric Simenel

doi:10.1142/S0218301315410050

Microscopic description of large amplitude collective motion in the nuclear astrophysics context

Denis Lacroix, Yusuke Tanimura, Guillaume Scamps, Cédric Simenel

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

In the last 10 years, we have observed an important increase of interest in the application of time-dependent energy density functional (TD-EDF) theory. This approach allows to treat nuclear structure and nuclear reaction from small to large amplitude dynamics in a unified framework. The possibility to perform unrestricted three-dimensional simulations using state-of-the-art effective interactions has opened new perspectives. In the present paper, an overview of applications where the predictive power of TD-EDF has been benchmarked is given. A special emphasize is made on processes that are of astrophysical interest. Illustrations discussed here include giant resonances, fission, binary and ternary collisions leading to fusion, transfer and deep inelastic processes.

Original language	English
Article number	1541005
Journal	International Journal of Modern Physics E
Volume	24
Issue number	9
DOIs	https://doi.org/10.1142/S0218301315410050
Publication status	Published - 29 Sept 2015

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title = "Microscopic description of large amplitude collective motion in the nuclear astrophysics context",

abstract = "In the last 10 years, we have observed an important increase of interest in the application of time-dependent energy density functional (TD-EDF) theory. This approach allows to treat nuclear structure and nuclear reaction from small to large amplitude dynamics in a unified framework. The possibility to perform unrestricted three-dimensional simulations using state-of-the-art effective interactions has opened new perspectives. In the present paper, an overview of applications where the predictive power of TD-EDF has been benchmarked is given. A special emphasize is made on processes that are of astrophysical interest. Illustrations discussed here include giant resonances, fission, binary and ternary collisions leading to fusion, transfer and deep inelastic processes.",

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AU - Tanimura, Yusuke

AU - Scamps, Guillaume

AU - Simenel, Cédric

PY - 2015/9/29

Y1 - 2015/9/29

N2 - In the last 10 years, we have observed an important increase of interest in the application of time-dependent energy density functional (TD-EDF) theory. This approach allows to treat nuclear structure and nuclear reaction from small to large amplitude dynamics in a unified framework. The possibility to perform unrestricted three-dimensional simulations using state-of-the-art effective interactions has opened new perspectives. In the present paper, an overview of applications where the predictive power of TD-EDF has been benchmarked is given. A special emphasize is made on processes that are of astrophysical interest. Illustrations discussed here include giant resonances, fission, binary and ternary collisions leading to fusion, transfer and deep inelastic processes.

AB - In the last 10 years, we have observed an important increase of interest in the application of time-dependent energy density functional (TD-EDF) theory. This approach allows to treat nuclear structure and nuclear reaction from small to large amplitude dynamics in a unified framework. The possibility to perform unrestricted three-dimensional simulations using state-of-the-art effective interactions has opened new perspectives. In the present paper, an overview of applications where the predictive power of TD-EDF has been benchmarked is given. A special emphasize is made on processes that are of astrophysical interest. Illustrations discussed here include giant resonances, fission, binary and ternary collisions leading to fusion, transfer and deep inelastic processes.

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KW - transport theory

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Microscopic description of large amplitude collective motion in the nuclear astrophysics context

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