Classical dynamical modelling of near-barrier breakup

E. C. Simpson; K. J. Cook; Sunil Kalkal; D. H. Luong; I. P. Carter; M. Dasgupta; D. J. Hinde

doi:10.1051/epjconf/201716300056

Classical dynamical modelling of near-barrier breakup

E. C. Simpson, K. J. Cook, Sunil Kalkal, D. H. Luong, I. P. Carter, M. Dasgupta, D. J. Hinde

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

4 Citations (Scopus)

Abstract

The complete fusion of light, weakly-bound nuclides is known to be significantly suppressed with respect to comparable well-bound projectiles or with respect to single barrier penetration model calculations. Strong α-clustering in these light systems mean that they very easily disintegrate into clusters, either via direct excitation of their intrinsic cluster continuum, or via transfer reactions which connect to unbound states in neighbouring nuclides. This breakup is thought to reduce the probability for complete fusion. Here we discuss which processes cause breakup, whether or not breakup happens fast enough, and the interpretation of measurements made at the Australian National University of breakup using classical dynamical models. Understanding the intimate details of breakup, and the resonances through which it proceeds, will be crucial in determining its likely influence on fusion.

Original language	English
Article number	00056
Journal	EPJ Web of Conferences
Volume	163
DOIs	https://doi.org/10.1051/epjconf/201716300056
Publication status	Published - 22 Nov 2017
Event	FUSION 2017 - Hobart, Australia Duration: 20 Feb 2017 → 24 Feb 2017

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title = "Classical dynamical modelling of near-barrier breakup",

abstract = "The complete fusion of light, weakly-bound nuclides is known to be significantly suppressed with respect to comparable well-bound projectiles or with respect to single barrier penetration model calculations. Strong α-clustering in these light systems mean that they very easily disintegrate into clusters, either via direct excitation of their intrinsic cluster continuum, or via transfer reactions which connect to unbound states in neighbouring nuclides. This breakup is thought to reduce the probability for complete fusion. Here we discuss which processes cause breakup, whether or not breakup happens fast enough, and the interpretation of measurements made at the Australian National University of breakup using classical dynamical models. Understanding the intimate details of breakup, and the resonances through which it proceeds, will be crucial in determining its likely influence on fusion.",

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T1 - Classical dynamical modelling of near-barrier breakup

AU - Simpson, E. C.

AU - Cook, K. J.

AU - Kalkal, Sunil

AU - Luong, D. H.

AU - Carter, I. P.

AU - Dasgupta, M.

AU - Hinde, D. J.

PY - 2017/11/22

Y1 - 2017/11/22

N2 - The complete fusion of light, weakly-bound nuclides is known to be significantly suppressed with respect to comparable well-bound projectiles or with respect to single barrier penetration model calculations. Strong α-clustering in these light systems mean that they very easily disintegrate into clusters, either via direct excitation of their intrinsic cluster continuum, or via transfer reactions which connect to unbound states in neighbouring nuclides. This breakup is thought to reduce the probability for complete fusion. Here we discuss which processes cause breakup, whether or not breakup happens fast enough, and the interpretation of measurements made at the Australian National University of breakup using classical dynamical models. Understanding the intimate details of breakup, and the resonances through which it proceeds, will be crucial in determining its likely influence on fusion.

AB - The complete fusion of light, weakly-bound nuclides is known to be significantly suppressed with respect to comparable well-bound projectiles or with respect to single barrier penetration model calculations. Strong α-clustering in these light systems mean that they very easily disintegrate into clusters, either via direct excitation of their intrinsic cluster continuum, or via transfer reactions which connect to unbound states in neighbouring nuclides. This breakup is thought to reduce the probability for complete fusion. Here we discuss which processes cause breakup, whether or not breakup happens fast enough, and the interpretation of measurements made at the Australian National University of breakup using classical dynamical models. Understanding the intimate details of breakup, and the resonances through which it proceeds, will be crucial in determining its likely influence on fusion.

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DO - 10.1051/epjconf/201716300056

M3 - Conference article

SN - 2101-6275

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JO - EPJ Web of Conferences

JF - EPJ Web of Conferences

M1 - 00056

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Y2 - 20 February 2017 through 24 February 2017

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Classical dynamical modelling of near-barrier breakup

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