l =1 coupling of single-particle orbitals in octupole deformed nuclei

Abstract

Conventionally, octupole deformation in nuclei has been attributed to strong l=3 couplings between opposite-parity single-particle orbitals. In this work, we demonstrate that the often-overlooked l=1 mode also plays an important role. Taking orbitals near the octupole magic number N = 134 as a benchmark, we systematically evaluate the l = 1 and l = 3 mixing ratios of the wave functions within the Nilsson model, interpreting the trends through matrix elements of the deformed potential. We introduce component-resolved single-particle octupole energy contributions, based on the Hellmann--Feynman relation, to quantify the contributions of each ( l, j) coupling. Furthermore, the impact of l = 1 coupling on the rotational structure is demonstrated via particle-rotor model calculations for 221Ra and 223Th. Our work suggests that l=1 and l=3 octupole couplings act synergistically in driving reflection asymmetry, necessitating a revised paradigm for understanding octupole correlation.