Your search keyword '"Bezzina L. T."' showing total 2 results

1. Interplay of charge clustering and weak binding in reactions of 8Li.

Author

Cook, K. J., Carter, I. P., Simpson, E. C., Dasgupta, M., Hinde, D. J., Bezzina, L. T., Kalkal, Sunil, Sengupta, C., Simenel, C., Swinton-Bland, B. M. A., Vo-Phuoc, K., and Williams, E.

Subjects

*COLLISIONS (Nuclear physics), *NUCLIDES, *PARTICLES (Nuclear physics)

Abstract

In collisions of light, stable, weakly bound nuclides, complete fusion (capture of all of the projectile charge) has been found to be suppressed by ∼30% at above-barrier energies. This is thought to be related to their low thresholds for breakup into charged clusters. The observation of fusion suppression in the neutron-rich radioactive nucleus 8Li is therefore puzzling: the lowest breakup threshold yields 7Li+n which cannot contribute to fusion suppression because 7Li retains all the projectile charge. In this work, the full characteristics of 8Li breakup in reactions with 209Bi are presented, including, for the first time, coincidence measurements of breakup into charged clusters. Correlations of cluster fragments show that most breakup occurs too slowly to significantly suppress fusion. However, a large cross section for unaccompanied α particles was found, suggesting that charge clustering, facilitating partial charge capture, rather than weak binding is the crucial factor in fusion suppression, which may therefore persist in exotic nuclides. [ABSTRACT FROM AUTHOR]

Published

2018

2. Origins of Incomplete Fusion Products and the Suppression of Complete Fusion in Reactions of ^{7}Li.

Author

Cook KJ, Simpson EC, Bezzina LT, Dasgupta M, Hinde DJ, Banerjee K, Berriman AC, and Sengupta C

Abstract

Above-barrier complete fusion involving nuclides with low binding energy is typically suppressed by 30%. The mechanism that causes this suppression, and produces the associated incomplete fusion products, is controversial. We have developed a new experimental approach to investigate the mechanisms that produce incomplete fusion products, combining singles and coincidence measurements of light fragments and heavy residues in ^{7}Li+^{209}Bi reactions. For polonium isotopes, the dominant incomplete fusion product, only a small fraction can be explained by projectile breakup followed by capture: the dominant mechanism is triton cluster transfer. Suppression of complete fusion is therefore primarily a consequence of clustering in weakly bound nuclei rather than their breakup prior to reaching the fusion barrier. This implies that suppression of complete fusion will occur in reactions of nuclides where strong clustering is present.

Published

2019