Z. X. Ren, P. W. Zhao, S. Q. Zhang, J. Meng
Published 2019-03-18Version 1
The toroidal states in $^{28}$Si with spin extending to extremely high are investigated with the cranking covariant density functional theory on a 3D lattice. Thirteen toroidal states with spin $I$ ranging from 0 to 56$\hbar$ are obtained, and their stabilities against particle emissions are studied by analyzing the density distributions and potentials. The excitation energies of the toroidal states at $I=28$, 36, 44$\hbar$ reasonably reproduce the observed three resonances extracted from the 7-$\alpha$ de-excitation of $^{28}$Si. The $\alpha$ clustering of these toroidal states is supported by the $\alpha$-localization function.
Comments: 15 pages, 8 figures
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