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Multireference covariant density-functional theory for the low-lying states of odd-mass nuclei

E. F. Zhou, X. Y. Wu, J. M. Yao

2024Physical review. C10 citationsDOI

Abstract

We extend multireference covariant density-functional theory (MR-CDFT) based on a relativistic point-coupling energy functional to describe the low-lying states of odd-mass nuclei. The nuclear wave function is constructed as a superposition of quadrupole-octupole deformed mean-field configurations, with projection onto angular momentum, particle numbers, and parity within the framework of the generator coordinate method. Using $^{25}\mathrm{Mg}$ as an example, we calculate the energy spectrum, electric multipole, and magnetic dipole transition strengths based on three different schemes for the mean-field configurations of odd-mass nuclei. We find that the low-energy structure of $^{25}\mathrm{Mg}$ is reasonably reproduced in all three schemes. In particular, the effect of octupole correlation is illustrated in the application to the low-lying parity doublets of $^{21}\mathrm{Ne}$. This work demonstrates the success of the MR-CDFT for the low-lying states of odd-mass nuclei with possible strong quadruple-octupole correlations.

Topics & Concepts

Multipole expansionPhysicsQuadrupoleAtomic physicsCovariant transformationWave functionParity (physics)Angular momentumDipoleHamiltonian (control theory)Valence (chemistry)Quantum mechanicsMathematicsMathematical optimizationNuclear physics research studiesAtomic and Molecular PhysicsAdvanced Chemical Physics Studies
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