星际冰类似物中的原子加成反应

IF 2.5 2区 化学 Q3 CHEMISTRY, PHYSICAL
H. Linnartz, S. Ioppolo, G. Fedoseev
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引用次数: 99

摘要

在斯坦尼斯拉夫·莱姆1955年的科幻小说《麦哲伦云》中,前往另一颗恒星的工程师们发现他们的宇宙飞船由于未知的原因过热了。原因一定是在飞船外面,但显然那里只有空虚,至少与地面条件相比是这样。然而,恒星之间的空间,星际介质(ISM),并不是完全空的,在航天器的高速下,撞击粒子的横截面,即使是在这样一个稀释的环境中,也足以引起过热。60年后的今天,人们通过天文观测对ISM进行了详细的研究,在专门的实验室实验中进行了再现,并通过复杂的天体化学模型进行了模拟。的确,恒星之间的空间远非空空如也;它由气体、尘埃和冰组成,到目前为止检测到的分子既有小的(双原子)也有大的(长碳链、多环芳烃和富勒烯),既有稳定的,又有活性的(自由基、离子和激发态分子),证明了一种奇特而迷人的化学反应,发生在低密度、低温和强烈的辐射场中。天体化学家解释了在太空中观察到的化学复杂性——到目前为止已经确定了185种不同的分子(不包括同位素)——是气相和冰冷的尘埃颗粒反应的累积结果。气相模型解释了观测到的大部分物种的丰度,但无法解释稳定分子的数量密度,如水、甲醇或乙腈——最简单的氨基酸甘氨酸最有希望的前体物种之一——以及更大的化合物,如乙醇醛、二甲基醚和乙二醇。已经发现的证据表明,这些和其他复杂的物种,包括有机物种,都是在冰冷的尘埃颗粒上形成的,这些尘埃颗粒是分子形成的催化位点。在这里,粒子在高能和非高能的过程中“聚集、相遇和打招呼”(即冻结、扩散和反应),例如真空紫外线的照射,与撞击粒子(原子、电子和宇宙射线)的相互作用或加热。本文综述了基于实验室的星际冰化学研究的最新进展。重点是原子加成反应,说明了水、二氧化碳和甲醇如何在天文相关的温度下以固态形成,以及更复杂的物质的形成,如重要的益生元分子羟胺和最小的糖乙醇醛。这些反应在恒星和行星形成的“黑暗”时期尤其重要,也就是说,当紫外线的作用受到限制时。只有通过专门的实验室研究,即在温度、原子通量和冰形态等大量参数的完全控制下,才能对这些过程进行定量表征。得到的数字、物理和化学常数,如势垒高度、反应速率和分支比,提供了分子过程的信息,并且需要作为天体化学模型的输入,以便将实验室设置的典型时间尺度连接到理解ISM进化阶段所需的时间尺度。讨论了实验的细节以及结果的天体化学影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Atom addition reactions in interstellar ice analogues
It was in ‘The Magellanic Cloud’ (1955) – a science fiction novel by Stanislaw Lem – that engineers travelling to another star noticed that their spacecraft for unknown reasons overheated. The cause had to be outside the spaceship, but obviously there was only emptiness, at least compared to terrestrial conditions. The space between the stars, the interstellar medium (ISM), however, is not completely empty and at the high speed of the spacecraft the cross-section with impacting particles, even from such a dilute environment, was found to be sufficient to cause an overheating. Today, 60 years later, the ISM has been studied in detail by astronomical observations, reproduced in dedicated laboratory experiments and simulated by complex astrochemical models. The space between the stars is, indeed, far from empty; it comprises gas, dust and ice and the molecules detected so far are both small (diatomics) and large (long carbon chains, PAHs and fullerenes), stable and reactive (radicals, ions, and excited molecules) evidencing an exotic and fascinating chemistry, taking place at low densities, low temperatures and experiencing intense radiation fields. Astrochemists explain the observed chemical complexity in space – so far 185 different molecules (not including isotopologues) have been identified – as the cumulative outcome of reactions in the gas phase and on icy dust grains. Gas phase models explain the observed abundances of a substantial part of the observed species, but fail to explain the number densities for stable molecules, as simple as water, methanol or acetonitrile – one of the most promising precursor species for the simplest amino acid glycine – as well as larger compounds such as glycolaldehyde, dimethylether and ethylene glycol. Evidence has been found that these and other complex species, including organic ones, form on icy dust grains that act as catalytic sites for molecule formation. It is here where particles ‘accrete, meet, and greet’ (i.e. freeze out, diffuse and react) upon energetic and non-energetic processing, such as irradiation by vacuum UV light, interaction with impacting particles (atoms, electrons and cosmic rays) or heating. This review paper summarises the state-of-the-art in laboratory based interstellar ice chemistry. The focus is on atom addition reactions, illustrating how water, carbon dioxide and methanol can form in the solid state at astronomically relevant temperatures, and also the formation of more complex species such as hydroxylamine, an important prebiotic molecule, and glycolaldehyde, the smallest sugar, is discussed. These reactions are particularly relevant during the ‘dark’ ages of star and planet formation, i.e. when the role of UV light is restricted. A quantitative characterization of such processes is only possible through dedicated laboratory studies, i.e. under full control of a large set of parameters such as temperature, atom-flux, and ice morphology. The resulting numbers, physical and chemical constants, e.g. barrier heights, reaction rates and branching ratios, provide information on the molecular processes at work and are needed as input for astrochemical models, in order to bridge the timescales typical for a laboratory setting to those needed to understand the evolutionary stages of the ISM. Details of the experiments as well as the astrochemical impact of the results are discussed.
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来源期刊
CiteScore
14.20
自引率
1.60%
发文量
5
审稿时长
1 months
期刊介绍: International Reviews in Physical Chemistry publishes review articles describing frontier research areas in physical chemistry. Internationally renowned scientists describe their own research in the wider context of the field. The articles are of interest not only to specialists but also to those wishing to read general and authoritative accounts of recent developments in physical chemistry, chemical physics and theoretical chemistry. The journal appeals to research workers, lecturers and research students alike.
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