Property of the low-lying states at the critical point of the phase transition in U(4) vibron model

TL;DR

This paper investigates the properties of low-lying states at the critical point of a phase transition in the U(4) vibron model, comparing theoretical models and experimental data to understand their characteristics.

Contribution

It provides a detailed analysis of the energy spectra and transition rates at the critical point, highlighting the effectiveness of the r^4 potential and E(3) symmetry in describing these states.

Findings

r^4 potential model captures classical limit behavior at the critical point

E(3) symmetry over-predicts energy levels and under-predicts transition rates

Empirical evidence from 12C+12C system supports the model's relevance

Abstract

We study the properties of the low-lying states at the critical point of the phase transition from U(3) to O(4) symmetry in the U(4) vibron model in detail. By analyzing the general characteristics and comparing the calculated results of the energy spectra and the E1, E2 transition rates in E(3) symmetry, in $r^4$ potential model and the finite boson number case in boson space, we find that the results in the $r^4$ potential demonstrates the characteristic of the classical limit at the critical point well and the E(3) symmetry over-predict the energy levels and under-predict the E1 and E2 transition rates of the states at the critical point. However, the E(3) symmetry may describe part of the properties of the system with boson number around 10 to 20. We also confirm that the 12C+12C system is an empirical evidence of the state at the critical point of the phase transition in the U(4) model when concerning the energies of the low-lying resonant states.