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Emergence of High-Order Deformation in Rotating Transfermium Nuclei: A Microscopic Understanding

F. F. Xu, Y. K. Wang, Yiping Wang, P. Ring, P. W. Zhao

2024Physical Review Letters14 citationsDOIOpen Access PDF

Abstract

The rotational properties of the transfermium nuclei are investigated in the full deformation space by implementing a shell-model-like approach in the cranking covariant density functional theory on a three-dimensional lattice, where the pairing correlations, deformations, and moments of inertia are treated in a microscopic and self-consistent way. The kinematic and dynamic moments of inertia of the rotational bands observed in the transfermium nuclei ^{252}No, ^{254}No, ^{254}Rf, and ^{256}Rf are well reproduced without any adjustable parameters using a well-determined universal density functional. It is found for the first time that the emergence of the octupole deformation should be responsible for the significantly different rotational behavior observed in ^{252}No and ^{254}No. The present results provide a microscopic solution to the long-standing puzzle on the rotational behavior in No isotopes, and highlight the risk of investigating only the hexacontetrapole (β_{60}) deformation effects in rotating transfermium nuclei without considering the octupole deformation.

Topics & Concepts

Covariant transformationMoment of inertiaPhysicsDeformation (meteorology)PairingInertiaClassical mechanicsKinematicsLattice (music)SHELL modelShell (structure)Atomic physicsCondensed matter physicsQuantum mechanicsMaterials scienceSuperconductivityMeteorologyComposite materialAcousticsNuclear physics research studiesAdvanced Chemical Physics StudiesAtomic and Molecular Physics
Emergence of High-Order Deformation in Rotating Transfermium Nuclei: A Microscopic Understanding | Litcius