Prolate-oblate shape competition and impact on charge radii in Bk isotopes

Abstract

The nuclear charge radius provides a fundamental probe of nuclear structure, yet experimental data remain rare in the actinide region. Using the deformed relativistic Hartree-Bogoliubov theory in continuum (DRHBc) with the PC-PK1 functional, we carry out a systematic investigation of prolate-oblate shape competition in odd-A Bk isotopes. Deformation is found to play an important role in the description of charge radii rc by extending the density distribution. Notably, rc exhibits a distinct shape dependence: for a given absolute quadrupole deformation |β2|, oblate shapes yield larger charge radii than their prolate counterparts in well-deformed nuclei near the mid-shell region, where the empirical formula rc(β2) = (1 + 54π|β2|2) rc(0) fails to capture the observed behavior. This enhancement is attributed to a central depression (or ``bubble" structure) in the proton density, which microscopically originates from the non-occupation of the spherical 3s1/2(=1/2) orbital in oblate minima. These findings establish a clear microscopic connection between nuclear shape, single-particle occupancy, and nuclear size.

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