First evidence for the J$>$1 components of the pygmy dipole resonance in neutron-rich nuclei

TL;DR

This paper reports the first experimental evidence of J>1 components of the pygmy dipole resonance in neutron-rich nuclei, expanding understanding of nuclear structure and astrophysical element synthesis.

Contribution

It provides the first observation of J>1 PDR components in neutron-rich nuclei, revealing new resonant structures and extending the PDR concept beyond dipole states.

Findings

Identified J>1 components of PDR in $^{80}$Ge

Extended PDR concept beyond dipole states

Implications for nuclear structure and astrophysics

Abstract

Gamma ($\gamma$) decay shapes the synthesis of heavy elements in neutron-rich nuclear environments of neutron star mergers, supplying the Universe with heavy elements. The low-energy pygmy dipole resonance (PDR) influences nuclear reaction rates of the rapid nucleosynthesis through enhanced $\gamma$ transitions. However, since it is difficult to reproduce astrophysical conditions in laboratories, PDR was previously observed only in $J = 1$ spin states. Here we report the first experimental observation of $J > 1$ components of PDR, identified in the $\beta$-delayed $\gamma$ decay of the J$^{\pi}$ = 3$^{-}$ spin-parity isomer of $^{80}$Ga. The data analysis, combined with decay information and theoretical calculations allows the identification of resonant structures below the neutron emission threshold of the neutron-rich germanium $^{80}$Ge as J$^{\pi} = (2,3)^-$ components of the PDR built on the low-lying J$^{\pi}$ = 2$^+$ quadrupole state. Our findings extend the concept of PDR beyond dipole states, with implications for nuclear structure theory and experiment, as well as the element production in the cosmos.