First experimental determination of the radiative-decay probability of the [formula omitted] state in 12C for estimating the triple alpha reaction rate in high temperature environments

M Tsumura,T Furuno,N Kobayashi,I Ou,A Sakaue,A Tamii,S Ashikaga,H Akimune,M Ichikawa,T Baba,N Itagaki,J Zenihiro,H Fujimura,T Nanamura,K Inaba,Y Matsuda,Y Maeda,T Kawabata,K Watanabe,A Koshikawa,K Miki,S Kubono,Masatoshi Itoh ,Satoshi Adachi ,Kenta Suzuki ,Hiroyuki Fujioka ,Mariko Murata ,Yoshiki Watanabe ,Yoshinori Ishii ,Chihiro Iwamoto ,H P Yoshida ,Tomoya Takeda ,Takeshi Harada ,Toshikazu Hashimoto ,Michele Sferrazza ,Yasuhiro Takahashi ,Takahiro Morimoto ,Shigenori Matsumoto ,Yuki Fujikawa ,Satoshi Sakaguchi

doi:10.1016/j.physletb.2021.136283

Abstract

The triple alpha reaction is one of the most important reactions in the nuclear astrophysics. However, its reaction rate in high temperature environments at T9> 2 was still uncertain. One of the major origins of the uncertainty was that the radiative-decay probability of the 31− state in 12C was unknown. In the present work, we have determined the radiative-decay probability of the 31− state to be 1.3−1.1+1.2×10−6 by measuring the 1H(12C,12Cp) reaction for the first time, and derived the triple alpha reaction rate in high temperature environments from the measured radiative-decay probability. The present result suggests that the 31− state noticeably enhances the triple alpha reaction rate although the contribution from the 31− state had been assumed to be small.

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