Synthesis mechanism of superheavy element 120: a dinuclear system model approach with microscopic inputs

Abstract

The dinuclear system model incorporates several essential input physical quantities, including nuclear mass, fission barrier, shell correction energy, level density parameter, and shell damping factor, etc., which are derived from diverse nuclear structure models. To achieve theoretical consistency, we try to generate these essential input physical quantities from the finite-temperature covariant density functional theory using PC-PK1 energy density functional, with pairing correlations treated via the BCS approach. With microscopically determined input parameters, the dinuclear system model can successfully reproduce experimental results for: (i) cold fusion reaction systems (48Ca + 204,206-208Pb → 252,254-256No*), and (ii) hot fusion reaction systems (48Ca + 239,240,242,244Pu → 287,288,290,292Fl*). Furthermore, we perform calculations for the fusion reactions 50Ti+249Cf, 51V+249Bk, 54Cr+248Cm, and 55Mn+243Am, targeting the synthesis of element 120. It is found that the maximum synthesis cross section for these four reactions are 48.20 fb, 12.33 fb, 5.25 fb, 0.47 fb corresponding to 50Ti(249Cf,4n)295120 at E* CN = 41 MeV, 51V(249Bk,3n)297120 at E* CN = 34 MeV, 54Cr(248Cm,3n)299120 at E* CN = 32 MeV, 55Mn(243Am,5n)293120 at E* CN = 53 MeV, respectively.