太阳祖先普查及其对太阳系化学成分的贡献

IF 5.4 2区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Astronomy & Astrophysics Pub Date : 2024-10-29 DOI:10.1051/0004-6361/202451076

F. Fiore, F. Matteucci, E. Spitoni, M. Molero, P. Salucci, D. Romano, A. Vasini

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引用次数: 0

摘要

在这项工作中，我们计算了造成太阳系化学组成的不同类型恒星和现象（超新星、新星、白矮星、合并中子星、黑洞）的速率和数量。在宇宙大爆炸期间，只形成了轻元素，而从碳到铀等所有重元素都是在恒星内部产生的。恒星死亡后，将新形成的元素释放到星际气体中。这个过程被称为 "化学进化"。我们特别分析了所有质量恒星的死亡率，无论它们是静态死亡还是爆炸死亡。这些速率和恒星总数是在修订版的银河化学演化 "两陨模型 "的背景下计算得出的，该模型相对较好地再现了观测到的几种化学物质的丰度模式、全球太阳金属性以及当前的气体、恒星和总表面质量密度。我们还计算了曾经诞生并仍然存活的恒星总数，以及在太阳系形成之前诞生的质量和金属度与太阳类似的恒星数量。后一个数字包含了太阳系附近所有可能存在的、能够孕育生命的太阳系。我们得出的结论是，在所有从宇宙大爆炸到太阳系形成之前诞生和死亡的恒星（从 0.8 到 100 M⊙）中，93.00%是以单颗白矮星形式死亡的恒星（没有与伴星发生显著的相互作用），它们的质量范围在 0.8 M⊙；5.24%是中子星，0.73%是黑洞，两者都起源于核心坍缩超新星（M > 8 M⊙）；0.64%是Ia型超新星，0.40%是新星系统，两者都起源于与白矮星相同的质量范围。从宇宙大爆炸到太阳系形成之前，金属性在12+log(Fe/H)= 7.50 ± 0.04 dex范围内的与太阳类似的恒星数量约为31-107颗，尤其是我们的太阳是第2.61-107颗此类恒星。

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A census of the Sun’s ancestors and their contributions to the Solar System chemical composition

In this work, we compute the rates and numbers of different types of stars and phenomena (supernovae, novae, white dwarfs, merging neutron stars, black holes) that contributed to the chemical composition of the Solar System. During the Big Bang, only light elements formed, while all the heavy ones, from carbon to uranium and beyond, have since been created inside stars. Stars die and release the newly formed elements into the interstellar gas. This process is called ‘chemical evolution’. In particular, we analyse the death rates of stars of all masses, whether they die quiescently or explosively. These rates and total star numbers are computed in the context of a revised version of the two-infall model for the chemical evolution of the Milky Way, which reproduces the observed abundance patterns of several chemical species, the global solar metallicity, and the current gas, stellar, and total surface mass densities relatively well. We also compute the total number of stars ever born and still alive as well as the number of stars born up to the formation of the Solar System with mass and metallicity like those of the Sun. This latter number accounts for all the possible existing Solar systems that can host life in the solar vicinity. We conclude that, among all the stars (from 0.8 to 100 M_{⊙_{) that were born and died from the Big Bang up until the Solar System formation epoch and that contributed to its chemical composition, 93.00% were stars that died as single white dwarfs (without interacting significantly with a companion star) and originated in the mass range of 0.8–8 M_{⊙_{, while 5.24% were neutron stars and 0.73% were black holes, both originating from core-collapse supernovae (M > 8 M_{⊙_{); 0.64% were Type Ia supernovae and 0.40% were nova systems, both originating from the same mass range as the white dwarfs. The number of stars similar to the Sun born from the Big Bang up until the formation of the Solar System, with metallicity in the range 12+log(Fe/H)= 7.50 ± 0.04 dex, is ~31•10^{7^{, and in particular our Sun is the ~2.61• 10^{7^{-th star of this kind.}}}}}}}}}}

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来源期刊

Astronomy & Astrophysics 地学天文-天文与天体物理

CiteScore

10.20

自引率

27.70%

发文量

2105

审稿时长

1-2 weeks

期刊介绍： Astronomy & Astrophysics is an international Journal that publishes papers on all aspects of astronomy and astrophysics (theoretical, observational, and instrumental) independently of the techniques used to obtain the results.