Improved precision on the experimental E0 decay branching ratio of the Hoyle state

Abstract

Stellar carbon synthesis occurs exclusively via the 3α process, in which three α particles fuse to form 12C in the excited Hoyle state, followed by electromagnetic decay to the ground state. The Hoyle state is above the α threshold, and the rate of stellar carbon production depends on the radiative width of this state. The radiative width cannot be measured directly, and must instead be deduced by combining three separately measured quantities. One of these quantities is the E0 decay branching ratio of the Hoyle state, and the current 10\% uncertainty on the radiative width stems mainly from the uncertainty on this ratio. The E0 branching ratio was deduced from a series of pair conversion measurements of the E0 and E2 transitions depopulating the 0+2 Hoyle state and 2+1 state in 12C, respectively. The excited states were populated by the 12C(p,p) reaction at 10.5 MeV beam energy, and the pairs were detected with the electron-positron pair spectrometer, Super-e, at the Australian National University. The deduced branching ratio required knowledge of the proton population of the two states, as well as the alignment of the 2+1 state in the reaction. For this purpose, proton scattering and γ-ray angular distribution experiments were also performed. An E0 branching ratio of E0π/=8.2(5)×10-6 was deduced in the current work, and an adopted value of E0π/=7.6(4)×10-6 is recommended based on a weighted average of previous literature values and the new result. The new recommended value for the E0 branching ratio is about 14% larger than the previous adopted value of E0π/=6.7(6)×10-6, while the uncertainty has been reduced from 9% to 5%.