基于密度泛函理论的相互作用玻色子模型中的配对振动

K. Nomura, D. Vretenar, Z. P. Li, J. Xiang
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引用次数: 3

摘要

基于核密度泛函理论,提出了一种在相互作用玻色子模型(IBM)框架下结合形状和配对集体自由度之间耦合的方法。为了解释配对振动,引入了玻色子数非守恒的IBM哈密顿量。利用基于普适能量密度泛函和配对力的自洽平均场计算解,在轴对称四极子和配对本征变形约束下构造哈密顿量。通过将得到的四极配对势能面映射到玻色子凝聚态的玻色子哈密顿量的期望值上,确定了玻色子哈密顿量的强度参数。对$^{122}$Xe进行了说明计算,并在更系统的稀土$N=92$等音研究中进一步探索了该方法。动态配对自由度的加入显著降低了基于激发态$0 +$的能带的能量。结果与光谱数据在定量上一致,并与使用集体哈密顿方法得到的结果一致。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Pairing vibrations in the interacting boson model based on density functional theory
We propose a method to incorporate the coupling between shape and pairing collective degrees of freedom in the framework of the interacting boson model (IBM), based on the nuclear density functional theory. To account for pairing vibrations, a boson-number non-conserving IBM Hamiltonian is introduced. The Hamiltonian is constructed by using solutions of self-consistent mean-field calculations based on a universal energy density functional and pairing force, with constraints on the axially-symmetric quadrupole and pairing intrinsic deformations. By mapping the resulting quadrupole-pairing potential energy surface onto the expectation value of the bosonic Hamiltonian in the boson condensate state, the strength parameters of the boson Hamiltonian are determined. An illustrative calculation is performed for $^{122}$Xe, and the method is further explored in a more systematic study of rare-earth $N=92$ isotones. The inclusion of the dynamical pairing degree of freedom significantly lowers the energies of bands based on excited $0^+$ states. The results are in quantitative agreement with spectroscopic data, and are consistent with those obtained using the collective Hamiltonian approach.
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