Metal-poor stars with detailed information available about their chemical inventory pose powerful empirical benchmarks for nuclear astrophysics. Here we present our spectroscopic chemical abundance investigation of the metal-poor ([Fe/H]?=??1.60?±?0.03 dex), r -process-enriched ([Eu/Fe]?=?0.73?±?0.10 dex) halo star HD 20 , using novel and archival high-resolution data at outstanding signal-to-noise ratios (up to ~1000 ?~(?1)). By combining one of the first asteroseismic gravity measurements in the metal-poor regime from a TESS light curve with the spectroscopic analysis of iron lines under non-local thermodynamic equilibrium conditions, we derived a set of highly accurate and precise stellar parameters. These allowed us to delineate a reliable chemical pattern that is comprised of solid detections of 48 elements, including 28 neutron-capture elements. Hence, we establish HD 20 among the few benchmark stars that have nearly complete patterns and low systematic dependencies on the stellar parameters. Our light-element ( Z ?≤?30) abundances are representative of other, similarly metal-poor stars in the Galactic halo that exhibit contributions from core-collapse supernovae of type II. In the realm of the neutron-capture elements, our comparison to the scaled solar r -pattern shows that the lighter neutron-capture elements ( Z ???60) are poorly matched. In particular, we find imprints of the weak r -process acting at low metallicities. Nonetheless, by comparing our detailed abundances to the observed metal-poor star BD +17 3248, we find a persistent residual pattern involving mainly the elements Sr, Y, Zr, Ba, and La. These are indicative of enrichment contributions from the s -process and we show that mixing with material from predicted yields of massive, rotating AGB stars at low metallicity improves the fit considerably. Based on a solar ratio of heavy- to light- s elements – which is at odds with model predictions for the i -process – and a missing clear residual pattern with respect to other stars with claimed contributions from this process, we refute (strong) contributions from such astrophysical sites providing intermediate neutron densities. Finally, nuclear cosmochronology is used to tie our detection of the radioactive element Th to an age estimate for HD 20 of 11.0?±?3.8 Gyr.
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机译:金属贫乏明星,提供关于他们的化学品库存的详细信息,对核天体物理学的强大实证基准。在这里,我们介绍了我们的金属差([Fe / H] = =α1.60?±0.03°Dex),R-Process--riched([Eu / Fe]?=?0.73?±±0.10 DEX)Halo Star HD 20,使用新颖和档案高分辨率数据以出色的信号 - 噪声比(最高〜1000?〜(?1))。通过在非局部热力学平衡条件下的铁管线的光谱分析中将第一张光痉挛重力测量与金属较差的重力测量相结合,我们衍生了一组高精度和精确的恒星参数。这些允许我们描绘一种可靠的化学品,其由48个元素的固体检测组成,包括28个中子捕获元素。因此,我们在几乎完全的模式和恒星参数上具有几乎完整的模式和低系统依赖性的基准恒星中建立了HD 20。我们的光元素(Z?≤≤30)丰富的是其他,在银河系中的其他金属差的恒星中,其表现出II型核心塌陷超新星的贡献。在中子捕获元件的领域中,我们与缩放的太阳能R -Pattern的比较表明,更轻的中子捕获元件(Z ??? 60)匹配不佳。特别是,我们发现在低金属上作用的弱R-process的印记。尽管如此,通过将我们的详细丰富与观察到的金属差的星星BD +17 3248进行比较,我们发现持续存在的剩余模式,主要是元素SR,Y,Zr,Ba和La。这些表明来自S的富集贡献 - 方法,我们表明,用来自预测的大规模产量的材料混合,在低金属性下旋转AgB恒星可显着改善拟合。基于重度至光学元素的太阳能比 - 这与I-Process的模型预测有所不同 - 以及与此过程中声称贡献的其他恒星相对于其他恒星的缺失明显的剩余模式,我们反驳(强)从提供中子密度的诸如天体物理站点的贡献。最后,核心辅助核化学族用于将我们对13.0 HD 20的估计的检测到11.0±3.8 gyr。
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