Direct Reactions with Exotic Beams (DREB2016)

Investigation of $^{10}$Li resonance component in $^{11}$Li via the $^{11}$Li(p,d) reaction

15 Jul 2016, 11:45

15m

Scotiabank Theatre (St. Mary's University)

Contributed Oral/Poster New instrumentation for direct reaction studies of exotic nuclei

Speaker

Dr Alisher Sanetullaev (Saint Mary's University, TRIUMF, Inha University in Tashkent)

Description

The unbound system $^{10}$Li is of great interest for the description of the structure of the Borromean neutron halo nucleus $^{11}$Li [1,2]. Borromean neutron halo nuclei are unusual weakly bound states of a core nucleus plus two neutrons. No transfer reaction experiment has been done so far which directly looks at the sub-component $^{10}$Li within $^{11}$Li. While earlier measurements have indicated possible resonances in $^{10}$Li [3-6], it is still not well established which resonance contributes to the ground state configuration of $^{11}$Li and by what spectroscopic factor. To obtain such information a decisive way can be investigating the transfer of one-neutron from $^{11}$Li. The presentation will report observations on $^{10}$Li studied through the first measurement of the p($^{11}$Li,d) one-neutron transfer reaction at beam energy of 6A MeV. This was performed using a solid H2 target at the newly constructed IRIS facility at TRIUMF. The $^{10}$Li residue was populated strongly as a resonance with energy Er = 0.62 ± 0.04 MeV having a total width Γ = 0.33 ± 0.07 MeV. The angular distribution of this resonance is characterized by neutron occupying the 1p1/2 orbital. A DWBA analysis yields a spectroscopic factor of 0.67 ± 0.12 for p1/2 removal strength from the ground state of $^{11}$Li to the region of the peak. The presentation will report observations on $^{10}$Li studied through the first measurement of the p($^{11}$Li,d) one-neutron transfer reaction at beam energy of 6A MeV. This was performed using a solid H2 target at the newly constructed IRIS facility at TRIUMF. The $^{10}$Li residue was populated strongly as a resonance with energy Er = 0.62 ± 0.04 MeV having a total width Γ = 0.33 ± 0.07 MeV. The angular distribution of this resonance is characterized by neutron occupying the 1p1/2 orbital. A DWBA analysis yields a spectro- scopic factor of 0.67 ± 0.12 for p1/2 removal strength from the ground state of $^{11}$Li to the region of the peak. [1] E. Garrido, D.V. Fedorov, A.S. Jensen, Nucl. Phys. A 700 (2002) 117. [2] I. Tanihata, H. Savajols, R. Kanungo, Prog. in Part. and Nucl. Phys. 68 (2013) 215. [3] H.B. Jeppesen, A.M. Moro, U.C. Bergmann, et al., Phys. Lett. B 642 (2006) 449. [4] K.H. Wilcox, R.B. Weisenmiller, G.J. Wozniak, et al., Phys. Lett. B 59 (1975) 142. [5] A.I. Amelin, M.G. Gornov, Yu.B. Gurov, et al., Yad. Fiz. 52 (1990) 1231. [6] M. Zinser, F. Humbert, T. Nilsson, et al., Nuclear Phys. A 619 (1997) 151176.