Nuclear shapes of Nb isotopes

TL;DR

This study investigates the nuclear shapes and shape coexistence in odd-mass Nb isotopes ($^{93-103}$Nb) using the interacting boson-fermion model with configuration mixing, revealing configuration crossing and quantum phase transitions near $N=60$.

Contribution

It applies the IBFM-CM with configuration mixing to analyze shape coexistence and quantum phase transitions in Nb isotopes, highlighting the influence of an unpaired nucleon.

Findings

Evidence of shape coexistence and configuration crossing around $N=60$

Identification of quantum phase transition in Nb isotopes

Unpaired nucleon affects the abruptness of the phase transition

Abstract

The study of the structure of odd-mass nuclei in regions characterized by the interplay of multiple particle-hole configurations represents a major challenge in nuclear structure physics. The odd-mass niobium isotopes ($Z = 41$), located near the $N = 60$ region, are of particular interest due to shape coexistence and quantum phase transitions. This work investigates the structure of the $^{93-103}$Nb isotopes using the intrinsic-frame formalism of the interacting boson-fermion model with configuration mixing (IBFM-CM), aiming to determine nuclear shapes and explore shape coexistence, configuration crossing, and quantum phase transitions. We employ the intrinsic formalism of the IBFM-CM, including both 0p-0h (regular) and 2p-2h (intruder) configurations interacting with the unpaired nucleon, providing a self-consistent framework to study energy surfaces, shape coexistence, and intruder bands for both positive- and negative-parity states. A realistic Hamiltonian for niobium, determined in previous studies, is adopted. The formalism is applied to the $^{93-103}$Nb isotopes for both positive- and negative-parity bands. A detailed analysis of the mean-field energy surfaces has been performed, including axial energy curves, triaxial energy surfaces in the $\beta-\gamma$ plane, and the corresponding equilibrium deformation parameters. The results reveal clear evidence of configuration coexistence and crossing along the isotopic chain. The existence of crossing configurations is demonstrated around $N = 60$, corresponding to a quantum phase transition previously identified in the Sr and Zr isotopic chains. Furthermore, the presence of an unpaired nucleon in Nb influences the abruptness of the quantum phase transition, underscoring the sensitivity of the structural evolution to single-particle degrees of freedom.