J. G. Duarte, A. Di Leva, R. Buompane, A. Formicola, J. T. Harke, D. Rapagnani, C. Santonastaso, L. Gialanella
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引用次数: 0
Abstract
The \(^{12}\)C(\(\alpha \),\(\gamma \))\(^{16}\)O reaction rate is crucial in determining the carbon-to-oxygen abundance ratio in stellar nucleosynthesis. Measuring this reaction’s cross section at stellar energies is challenging due to its extremely small value, approximately 10\(^{-17}\) barn at E\(_{\mathrm {c.m.}}\) = 300 keV. To address this, R-matrix calculations are employed to extrapolate data to lower energies, requiring a comprehensive understanding of each contribution to the cross section. The dominant contributions to the cross section at stellar energies arise from electric dipole (E1) and electric quadrupole (E2) transitions to the ground state of \(^{16}\)O, along with a significant cascade contribution. Traditionally, these contributions have been separated using the \(\gamma \)-ray angular distribution. In this work, we propose a novel technique using the energy distribution of the \(^{16}\)O recoils at the focal plane. This method involves a neural network trained on detailed Monte Carlo simulations of the energy distribution of recoils transported through the recoil mass separator ERNA. This approach enables the simultaneous determination of all three contributions with errors around 10% in the energy range E\(_{\mathrm {c.m.}}\) = 1.0–2.2 MeV. By employing this new technique, we aim to significantly improve the accuracy of determining the cross section of the \(^{12}\)C(\(\alpha \),\(\gamma \))\(^{16}\)O reaction at astrophysical energies.
在恒星核合成过程中,\(^{12}\) C(\(\alpha \), \(\gamma \)) \(^{16}\) O反应速率是决定碳氧丰度比的关键。在恒星能量下测量这个反应的横截面是很有挑战性的,因为它的值非常小,在E \(_{\mathrm {c.m.}}\) = 300 keV时大约为10 \(^{-17}\) barn。为了解决这个问题,采用r矩阵计算将数据外推到较低的能量,这需要全面了解对截面的每个贡献。在恒星能量下,对横截面的主要贡献来自电偶极子(E1)和电四极子(E2)向\(^{16}\) O基态的跃迁,以及显著的级联贡献。传统上,这些贡献是用\(\gamma \) -射线角分布分开的。在这项工作中,我们提出了一种利用\(^{16}\) O反冲在焦平面上的能量分布的新技术。该方法利用神经网络对通过后坐力质量分离器ERNA传输的后坐力的能量分布进行了详细的蒙特卡罗模拟。这种方法可以同时确定所有三个贡献,误差在10左右% in the energy range E\(_{\mathrm {c.m.}}\) = 1.0–2.2 MeV. By employing this new technique, we aim to significantly improve the accuracy of determining the cross section of the \(^{12}\)C(\(\alpha \),\(\gamma \))\(^{16}\)O reaction at astrophysical energies.
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