Direct Reactions with Exotic Beams (DREB2016)

Locations of breakup in reactions near the fusion barrier (Invited)

15 Jul 2016, 13:30

25m

Scotiabank Theatre (St. Mary's University)

Invited

Speaker

Dr Edward Simpson (Australian National University)

Description

Above barrier fusion of light, weakly-bound projectiles with heavy targets is known to be suppressed by 25-35% [1-3]. Direct breakup reactions were thought to significantly reduce the probability for fusion of the entire projectile. Transfer reactions populating unbound states in neighbouring nuclei, such as $^5$Li and $^8$Be, have also been found to be a significant trigger of projectile disintegration [4]. Understanding the detail of these processes is crucial [5]: breakup must occur prior to the reactants reaching their mutual barrier in order to suppress fusion. If narrow, long-lived resonances are populated (e.g., $^6$Li 3$^+$ τ≈3×10$^{-20}$ s, $^8$Be 0$^+$ τ≈10$^{-16}$ s), the projectile-like nucleus will remain intact until it reaches the barrier, so cannot suppress fusion. Short lived states (e.g., the $^8$Be 2$^+$) disintegrate more quickly, but with ~10$^{-21}$ s collision timescales their effect on fusion is not yet clear. Here we discuss recent Australian National University measurements of sub-barrier breakup, where absorption of the charged breakup fragments is minimal. We interpret these results using a classical dynamical model [6] that has been extended to account for the energies and lifetimes of resonant states, and discuss what the angular correlations of the fragments may reveal about the location of breakup. [1] M. Dasgupta et al., Phys. Rev. C 66, 041602(R) (2002). [2] Y. W. Wu et al., Phys. Rev. C 68, 044605 (2003). [3] M. Dasgupta et al., Phys. Rev. C 70, 024606 (2004). [4] D. H. Luong et al., Phys. Lett. B 695, 105 (2011); Phys. Rev. C 88, 034609 (2013). [5] E. C. Simpson et al., Phys. Rev. C 93, 024605 (2016) [6] A. Diaz-Torres et al., Phys. Rev. Lett. 98, 152701 (2007).

Presentation materials

Slides

DREB2016_Simpson_final.pdf