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Hartree–Fock–Bogoliubov theory for odd-mass nuclei with a time-odd constraint and application to deformed halo nuclei

Haruki Kasuya, Kenichi Yoshida

2020Progress of Theoretical and Experimental Physics27 citationsDOIOpen Access PDF

Abstract

Abstract We show that the lowest-energy solution of the Hartree–Fock–Bogoliubov (HFB) equation has even particle-number parity as long as the time-reversal symmetry is conserved in the HFB Hamiltonian without null eigenvalues. Based on this finding, we give a rigorous foundation for a method for solving the HFB equation to describe the ground state of odd-mass nuclei by employing a time-reversal antisymmetric constraint operator to the Hamiltonian, where one obtains directly the ground state as a self-consistent solution of the cranked-HFB-type equation. Numerical analysis is performed for the neutron-rich Mg isotopes with a reasonable choice for the operator, and it is demonstrated that the anomalous increase in the matter radius of $^{37}$Mg is well described when the last neutron occupies a low-angular-momentum orbital in the framework of the nuclear energy density functional method, revealing the deformed halo structure.

Topics & Concepts

PhysicsAntisymmetric relationHaloHamiltonian (control theory)Parity (physics)Ground stateConstraint (computer-aided design)NeutronEquation of stateOperator (biology)RADIUSMathematical physicsNuclear matterQuantum electrodynamicsNuclear drip lineQuantum mechanicsDifferential equationNuclear structureSymmetry (geometry)Nuclear physicsClassical mechanicsGravitational singularityAtomic nucleusState (computer science)Null (SQL)Nuclear physics research studiesQuantum Chromodynamics and Particle InteractionsPulsars and Gravitational Waves Research
Hartree–Fock–Bogoliubov theory for odd-mass nuclei with a time-odd constraint and application to deformed halo nuclei | Litcius