Magic numbers for superheavy nuclei in relativistic continuum Hartree-Bogoliubov theory

Abstract

The magic proton and neutron numbers are searched in the superheavy region with proton number Z=100 - 140 and neutron number N= (Z+30) - (2Z+32) by the relativistic continuum Hartree-Bogoliubov (RCHB) theory with interactions NL1, NL3, NLSH, TM1, TW99, DD-ME1, PK1, and PK1R. Based on the two-nucleon separation energies S2p and S2n, the two-nucleon gaps δ2p and δ2n, the shell correction energies Eshellp and Eshelln, the pairing energies Epairp and Epairn, and the pairing gaps p and n, Z=120, 132, and 138 and N=172, 184, 198, 228, 238, and 258 are suggested to be the magic numbers within the present approach. The α-decay half-lives are also discussed. In addition, the potential energy surfaces of possible doubly magic nuclei are obtained by the deformation-constrained relativistic mean field (RMF) theory, and the shell effects stabilizing the nuclei are investigated. Furthermore, the formation cross sections of 292172120 and 304184120 at the optimal excitation energy are estimated by a phenomenological cold fusion reactions model with the structure information extracted from the constrained RMF calculation.

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