Extremely large oblate deformation of the first excited state in 12C: a new challenge to modern nuclear theory

Abstract

A Coulomb-excitation study of the high-lying first excited state at 4.439 MeV in the nucleus 12C has been carried out using the 208Pb(12C,12C*)208Pb* reaction at 56 MeV and the Q3D magnetic spectrograph at the Maier-Leibnitz Laboratorium in Munich. High-statistics achieved with an average beam intensity of approximately 1011 ions/s together with state-of-the-art ab initio calculations of the nuclear dipole polarizability permitted the accurate determination of the spectroscopic quadrupole moment, Q_S(2_1+) = +0.076(30)~eb, in agreement with previous measurements. Combined with previous work, a weighted average of Q_S(2_1+) = +0.090(14) eb is determined, which includes the re-analysis of a similar experiment by Vermeer and collaborators, Q_S(2_1+) = +0.103(20)~eb. Such a large oblate deformation challenges modern nuclear theory and emphasizes the need of α clustering and associated triaxiality effects for full convergence of E2 collective properties.