X. J. Bao

TL;DR: In this paper, half-lives of cluster radioactivity treated as a very asymmetric spontaneous fission were investigated within the WKB barrier-penetration probability, and the potential barrier was constructed using a generalized liquid-drop model (GLDM), taking into account the nuclear proximity energy, the mass asymmetry, an accurate nuclear radius, a phenomenological pairing correction and the microscopic shell corrections.

TL;DR: In this article, the α-decay half-lives of recently synthesized superheavy nuclei (SHN) were investigated by employing a unified fission model (UFM) and Royer's analytical formula.

TL;DR: In this article, the superheavy nuclear production mechanism can be described by fusion reactions with the dinuclear system concept, in which the deformations of the two nuclei are assumed to stay at their ground state with nucleons transferring between them.

TL;DR: In this article, the authors tried to find a way to produce superheavy nuclei (SHN), which appear in the gap between the SHN synthesized by cold fusion and those by hot fusion, or those so far not yet been produced in the laboratory, using a radioactive beam projectile, and to test symmetric fusion reactions for gaining more neutrons to synthesize neutron-richer SHN based on the dinuclear system (DNS) model via cold fusion reactions.

TL;DR: The dependence of the evaporation residue cross section (ERCS) ability to produce superheavy nuclei (SHN) on the isospin of colliding nuclei is analyzed within the dinuclear system concept as discussed by the authors.