High-temperature dust formation in carbon-rich astrophysical environments

IF 12.9 1区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS Nature Astronomy Pub Date : 2024-10-23 DOI:10.1038/s41550-024-02393-7

Guy Libourel, Marwane Mokhtari, Vandad-Julien Rohani, Bernard Bourdon, Clément Ganino, Eric Lagadec, Philippe Vennéguès, Vincent Guigoz, François Cauneau, Laurent Fulcheri

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Abstract

Condensation processes, which are responsible for the main chemical differences between gas and solids in the Galaxy, are the major mechanisms that control the cycle of dust from evolved stars to planetary systems. However, they are still poorly understood, mainly because the thermodynamics and kinetic models of nucleation or grain growth lack experimental data. To bridge this gap, we used a large-volume three-phase alternating-current plasma torch to obtain a full high-temperature condensation sequence at an elevated carbon-to-oxygen ratio from a fluxed chondritic gas composition. We show that the crystallized suites of carbides, silicides, nitrides, sulfides, oxides and silicates and the bulk composition of the condensates are properly modelled by a kinetically inhibited condensation scenario controlled by gas flow. This validates the thermodynamic predictions of the condensation sequence at a high carbon-to-oxygen ratio. On this basis and using appropriate optical properties, we also demonstrate the influence of pressure on dust chemistry as well as the low probability of forming and detecting iron silicides in asymptotic giant branch C-rich circumstellar environments as well as in our chondritic meteorites. By demonstrating the potential of predicting dust mineralogy in these environments, this approach holds high promise for quantitatively characterizing dust composition and formation in diverse astrophysical settings.

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富碳天体物理环境中的高温尘埃形成

凝结过程是造成银河系中气体和固体之间主要化学差异的原因，也是控制尘埃从演化恒星到行星系统循环的主要机制。然而，人们对它们的了解还很不够，主要是因为成核或晶粒生长的热力学和动力学模型缺乏实验数据。为了弥补这一差距，我们使用大容量三相交流等离子体炬，从通量软玉体气体成分中获得了碳氧比升高条件下的完整高温冷凝序列。我们的研究表明，碳化物、硅化物、氮化物、硫化物、氧化物和硅酸盐的结晶组合以及冷凝物的主体成分都是由气体流动控制的动力学抑制冷凝情景所正确模拟的。这验证了高碳氧比下冷凝序列的热力学预测。在此基础上，利用适当的光学特性，我们还证明了压力对尘埃化学的影响，以及在渐近巨枝富含 C 的周星体环境和我们的软玉陨石中形成和探测到铁硅化物的低概率。通过展示在这些环境中预测尘埃矿物学的潜力，这种方法在定量描述各种天体物理环境中的尘埃成分和形成方面大有可为。

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来源期刊

Nature Astronomy Physics and Astronomy-Astronomy and Astrophysics

CiteScore

19.50

自引率

2.80%

发文量

252

期刊介绍： Nature Astronomy, the oldest science, has played a significant role in the history of Nature. Throughout the years, pioneering discoveries such as the first quasar, exoplanet, and understanding of spiral nebulae have been reported in the journal. With the introduction of Nature Astronomy, the field now receives expanded coverage, welcoming research in astronomy, astrophysics, and planetary science. The primary objective is to encourage closer collaboration among researchers in these related areas. Similar to other journals under the Nature brand, Nature Astronomy boasts a devoted team of professional editors, ensuring fairness and rigorous peer-review processes. The journal maintains high standards in copy-editing and production, ensuring timely publication and editorial independence. In addition to original research, Nature Astronomy publishes a wide range of content, including Comments, Reviews, News and Views, Features, and Correspondence. This diverse collection covers various disciplines within astronomy and includes contributions from a diverse range of voices.