Fusion cross section of the superheavy Z=120 nuclei within the relativistic mean-field formalism

Background: Isotopes of Z = 107-118 have been synthesized using cold fusion at GSI, Darmstadt, and hot fusion reactions at JINR, Dubna. Recently theoretical models have predicted Z = 120 with N = 184 as an island of stability in the superheavy valley. Hence it is crucial and exciting to predict theo...

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Bibliographic Details
Main Authors: Rana, Shilpa, Kumar, Raj, Bhuyan, M.
Format: Article
Published: Amer Physical Soc 2021
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Online Access:http://eprints.um.edu.my/27034/
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Institution: Universiti Malaya
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Summary:Background: Isotopes of Z = 107-118 have been synthesized using cold fusion at GSI, Darmstadt, and hot fusion reactions at JINR, Dubna. Recently theoretical models have predicted Z = 120 with N = 184 as an island of stability in the superheavy valley. Hence it is crucial and exciting to predict theoretically the possible combination of projectiles and targets for the synthesis of Z = 120, which can be informative for upcoming experiments. Purpose: Present theoretical investigations aim to explore the fusion characteristics of various isotopes of Z = 120 within the relativistic mean-field formalism. We predict the most suitable projectile-target combination for the synthesis of element Z = 120. The increase in fusion cross section of nuclei in the superheavy island directly signals the nuclear shell effects. Besides these, the analysis will be crucial and relevant for future experiments to synthesize superheavy nuclei. Methods: The microscopic nucleon-nucleon R3Y interaction and the density distributions for targets and projectiles are calculated using a relativistic mean-field formalism with the NL3* parameter set. These densities and R3Y nucleon-nucleon (NN) interaction are then used to calculate the nuclear interaction potential using the double folding approach. Seventeen different projectile-target combinations that allow a high N/Z ratio are considered in the present analysis to calculate the capture and/or fusion cross sections of various isotopes of Z = 120 within the l-summed Wong formula. Results: The nuclear density distributions for the interacting projectile and target nuclei are obtained from relativistic mean-field Lagrangian for the NL3* parameter set. The nucleus-nucleus interaction potential is estimated for seventeen possible projectile-target combinations using the mean-field density and the R3Y NN potential via a double folding approach. The fusion barriers are obtained by adding the Coulomb potential to the nucleus-nucleus interaction potential. Finally, the fusion and/or capture cross section is calculated for all the systems within the l-summed Wong formula. Further, the equivalent surface diffusion parameter is estimated to correlate the surface properties of interacting nuclei with the fusion cross section. Conclusions: The four Ti-based reactions with the heaviest available target Cf-x, namely, Ti-46+Cf-248, Ti-46+Cf-249, Ti-50+Cf-249, and Ti-50+Cf-252, and also Cr-54+Cm-250 are found to have the most suitable target-projectile combinations for the synthesis of various isotopes Z = 120. We also notice that Ca-48 beams merely provide the required number of protons to synthesize the element with Z = 120. We established a correlation among the surface properties of interacting nuclei with the fusion characteristics in terms of the equivalent surface diffusion parameter.