The observation of vibrating pear shapes in radon nuclei: update.

There is a large body of evidence that atomic nuclei can undergo octupole distortion and assume the shape of a pear. This phenomenon is important for measurements of electric-dipole moments of atoms, which would indicate CP violation and hence probe physics beyond the standard model of particle physics. Isotopes of both radon and radium have been identified as candidates for such measurements. Here, we have observed the low-lying quantum states in $^{224}$Rn and $^{226}$Rn by accelerating beams of these radioactive nuclei. We show that radon isotopes undergo octupole vibrations but do not possess static pear-shapes in their ground states. We conclude that radon atoms provide less favourable conditions for the enhancement of a measurable atomic electric-dipole moment. any measurable moment will be amplified if the nucleus has octupole collectivity and further enhanced by static-octupole deformation. Both radon and radium atoms have been identified as good candidates for these measurements. Here, we have accelerated beams of radioactive $^{224}$Rn and $^{226}$Rn and have observed the low-lying quantum states in these nuclei populated by Coulomb excitation, including additional states not assigned in our 2019 publication. We show that these radon isotopes undergo octupole vibrations but do not possess static pear-shapes in their ground states, thus providing less favourable conditions for enhancement of a measurable atomic electric-dipole moment.