Beyond the Coherent Coupled Channels Description of Nuclear Fusion

Dasgupta, M.; Hinde, David; Díaz-Torres, A.; Bouriquet, B.; Low, Catherine; Milburn, G. J.; Newton, J.O.

doi:10.1103/physrevlett.99.192701

Cited by 202 publications

(171 citation statements)

References 24 publications

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“…The ground state is seen to be very weakly populated in the products of these reactions, with excited states populated up to tens of MeV even at energies far below the Coulomb barrier. These results support the importance of including dissipative couplings generated by cluster transfer in fusion models, which may prove important to describing the fusion hindrance effects [4,9] that are seen at low energies.…”

Section: Heavy Ion Accelerator Symposium 2014supporting

confidence: 66%

“…Fusion cross sections have been seen to fall off much faster with energy than predicted by standard Coupled Channels (CC) approaches to calculate them below a certain threshold [2,3], calling into doubt the efficacy of these models in this regime [4]. An abundance of recent measurements has shown this hindrance effect to be present in a wide variety of systems [5][6][7][8], such that it appears to be a general feature of heavy ion fusion.…”

Section: Introductionmentioning

confidence: 99%

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Investigating energy dissipation through nucleon transfer reactions

Rafferty

Dasgupta

Hinde

et al. 2015

EPJ Web of Conferences

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Abstract. Nucleon and cluster transfer probabilities have been measured in the collisions of 16,18 O, 19 F with 204,208 Pb, 209 Bi for charge stripping channels down to ΔZ = -3. Strong evidence of correlated nucleon transfer has been observed in particular channels, and neighbouring systems are seen to differ significantly in their behaviour. New measurements were made using an improved ΔE-E telescope. The back-scattered projectilelike fragments were measured in the telescope at θ lab = 160.6 • , and in combination with monitor detectors at forward angles allowed determination of absolute transfer probabilities. The improved design allows isotopic yields to be measured with greater precision.

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Section: Heavy Ion Accelerator Symposium 2014supporting

confidence: 66%

Section: Introductionmentioning

confidence: 99%

Investigating energy dissipation through nucleon transfer reactions

Rafferty

Dasgupta

Hinde

et al. 2015

EPJ Web of Conferences

Self Cite

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show abstract

“…All sub-barrier fusion calculations assume that there exists an ion-ion potential V (R) which depends on the internuclear distance R. Most of the theoretical fusion studies are carried out with the coupled-channels (CC) method [21][22][23][24] in which one uses empirical ion-ion potentials (typically Woods-Saxon potentials, or double-folding potentials with frozen nuclear densities).…”

Section: Theoretical Formalism and Ion-ion Potentialsmentioning

confidence: 99%

Microscopic analysis of sub-barrier fusion enhancement in132Sn+40Ca versus132Sn
Oberacker
¹
,
Umar
²

2013
Phys. Rev. C
32
3
46
0
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We provide a theoretical analysis of recently measured fusion cross sections which show a surprising enhancement at low Ec.m. energies for the system 132 Sn+ 40 Ca as compared to the more neutron-rich system 132 Sn+ 48 Ca. Dynamic microscopic calculations are carried out on a threedimensional lattice with a time-dependent density-constrained density functional theory. There are no adjustable parameters, the only input is the Skyrme effective NN interaction. Heavy-ion potentials V (R), coordinate-dependent mass parameters M (R), and total fusion cross sections σ(Ec.m.) are calculated for both systems. We are able to explain the measured fusion enhancement in terms of the narrower width of the ion-ion potential for 132 Sn+ 40 Ca, while the barrier heights and positions are approximately the same in both systems.

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“…It would also be interesting to extend the measurement of fusion cross sections at lower energies for these systems in order to better understand the role of transfer reactions on the deep sub-barrier fusion hindrance recently observed [84,85].…”

Section: Discussionmentioning

confidence: 99%

Microscopic study ofCa40+Ni58,64fusion reactions

et al. 2016

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Background: Heavy-ion fusion reactions at energies near the Coulomb barrier are influenced by couplings between the relative motion and nuclear intrinsic degrees of freedom of the colliding nuclei. The time-dependent Hartree-Fock (TDHF) theory, incorporating the couplings at the meanfield level, as well as the coupled-channels (CC) method are standard approaches to describe low energy nuclear reactions. Purpose: To investigate the effect of couplings to inelastic and transfer channels on the fusion cross sections for the reactions 40 Ca+ 58 Ni and 40 Ca+ 64 Ni. Methods: Fusion cross sections around and below the Coulomb barrier have been obtained from coupled-channels (CC) calculations, using the bare nucleus-nucleus potential calculated with the frozen Hartree-Fock method and coupling parameters taken from known nuclear structure data. The fusion thresholds and neutron transfer probabilities have been calculated with the TDHF method.

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Beyond the Coherent Coupled Channels Description of Nuclear Fusion

Cited by 202 publications

References 24 publications

Investigating energy dissipation through nucleon transfer reactions

Investigating energy dissipation through nucleon transfer reactions

Microscopic analysis of sub-barrier fusion enhancement in132Sn+40Ca versus132Sn
Oberacker
¹
,
Umar
²

2013
Phys. Rev. C
32
3
46
0
View full text Add to dashboard Cite

Microscopic study ofCa40+Ni58,64fusion reactions

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Beyond the Coherent Coupled Channels Description of Nuclear Fusion

Cited by 202 publications

References 24 publications

Investigating energy dissipation through nucleon transfer reactions

Investigating energy dissipation through nucleon transfer reactions

Microscopic analysis of sub-barrier fusion enhancement in132Sn+40Ca versus132SnOberacker1, Umar2 2013Phys. Rev. C323460View full textAdd to dashboardCite

Microscopic study ofCa40+Ni58,64fusion reactions

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Resources

About

Microscopic analysis of sub-barrier fusion enhancement in132Sn+40Ca versus132Sn
Oberacker
¹
,
Umar
²

2013
Phys. Rev. C
32
3
46
0
View full text Add to dashboard Cite