Determination of resonances in Gamow window for 12C+12C fusion reaction via thick-target inverse kinematics method

Determination of resonances in Gamow window for 12C+12C fusion reaction via thick-target inverse kinematics method

The 12C+12C fusion reaction at deep subbarrier energies is important for understanding the carbon burning process in massive star and explosive binary systems. However, its reaction rates are very difficult to measure directly or evaluate by simple extrapolation due to the extremely small cross sect...

Full description

Saved in:
Bibliographic Details
Main Authors: Weike Nan, Youbao Wang, Jun Su, Yaode Sheng, Richard James deBoer, Yuqiang Zhang, Luyang Song, Fuqiang Cao, Chen Chen, Chao Dong, Yunju Li, Zhihong Li, Gang Lian, Wei Nan, Yangping Shen, Na Song, Shengquan Yan, Seng Zeng, Bing Guo, Weiping Liu
Format: Article
Language:English
Published: Elsevier 2025-03-01
Series:Physics Letters B
Subjects:
12C+12C fusion reaction
Discrete resonance structure
Thick-target inverse kinematics method
R-matrix analysis
Online Access:http://www.sciencedirect.com/science/article/pii/S0370269325001017
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The 12C+12C fusion reaction at deep subbarrier energies is important for understanding the carbon burning process in massive star and explosive binary systems. However, its reaction rates are very difficult to measure directly or evaluate by simple extrapolation due to the extremely small cross sections and complex resonance structures near the Gamow window. In this work, we use one of its exit channels, i.e. 23Na+p to populate the excited states of the compound nucleus 24Mg via the conventional thick-target inverse kinematics method. By applying γ-charged particle coincidence, we have obtained excitation functions for the proton and α emission channels, respectively, and derived the resonance parameters through a simultaneous multi-channel R-matrix analysis. It is clear that a series of discrete resonances exist in the most relevant excitation energy region of 24Mg. The astrophysical S-factor of the 12C+12C fusion reaction is evaluated by adopting a systematic reduced width for the entrance channel. In particular, branching ratios of the dominant four decay channels are estimated across the entire Gamow window of the 12C+12C fusion reactions. Significant fluctuations are shown that may have strong impacts on the final outcome of the carbon burning process.
ISSN:0370-2693

Similar Items