The decay of quadrupole-octupole $1^-$ states in $^{40}$Ca and $^{140}$Ce

TL;DR

This study investigates the decay behavior of two-phonon $1^-$ states in $^{40}$Ca and $^{140}$Ce using gamma-ray spectroscopy, providing insights into their structure and supporting their two-phonon character through experimental and theoretical analysis.

Contribution

It presents new experimental decay data for $^{40}$Ca and $^{140}$Ce and compares these with advanced theoretical models, confirming the two-phonon nature of the $1^-$ states.

Findings

Decay into specific states observed in both nuclei.

Transition strengths align with theoretical predictions.

Negative parity states identified in $^{44}$Ca.

Abstract

Background: Two-phonon excitations originating from the coupling of two collective one-phonon states are of great interest in nuclear structure physics. One possibility to generate low-lying $E1$ excitations is the coupling of quadrupole and octupole phonons. Purpose: In this work, the $\gamma$-decay behavior of candidates for the $(2_1^+\otimes 3_1^-)_{1^-}$ state in the doubly-magic nucleus $^{40}$Ca and in the heavier and semi-magic nucleus $^{140}$Ce is investigated. Methods: $(\vec{\gamma},\gamma')$ experiments have been carried out at the High Intensity $\gamma$-ray Source (HI${\gamma}$S) facility in combination with the high-efficiency $\gamma$-ray spectroscopy setup $\gamma^3$ consisting of HPGe and LaBr$_3$ detectors. The setup enables the acquisition of $\gamma$-$\gamma$ coincidence data and, hence, the detection of direct decay paths. Results: In addition to the known ground-state decays, for $^{40}$Ca the decay into the $3^-_1$ state was observed, while for $^{140}$Ce the direct decays into the $2^+_1$ and the $0^+_2$ state were detected. The experimentally deduced transition strengths and excitation energies are compared to theoretical calculations in the framework of EDF theory plus QPM approach and systematically analyzed for $N=82$ isotones. In addition, negative parities for two $J=1$ states in $^{44}$Ca were deduced simultaneously. Conclusions: The experimental findings together with the theoretical calculations support the two-phonon character of the $1^-_1$ excitation in the light-to-medium-mass nucleus $^{40}$Ca as well as in the stable even-even $N=82$ nuclei.