分析微通道中由流动驱动沉淀产生的早期硫化铁、碳酸盐和磷酸盐矿物类似物。

IF 3.5 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS Astrobiology Pub Date : 2024-02-01 DOI:10.1089/ast.2021.0088
Aaron Pital, Megan Bromley, Max Dorn, Jungkyu Kim, Amanda Stockton
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引用次数: 0

摘要

天体生物学界感兴趣的大多数化学和物理相互作用都受到所研究系统矿物学的影响。通常,这种矿物学发生在沉积物或类似沉积物的水微观环境中,其中的早期矿物与经过长期成岩作用而形成的成熟矿物有很大的不同,这与 pH 值、氧化还原状态、浓度和温度的复杂相互作用息息相关。这种相互关联性很难在实验室环境中重现,但对于理解生命系统的物理和化学需求如何改变以及如何被其地质环境所改变却至关重要。我们提出了一种在微通道内生产沉淀矿物类似物的简便方法,并通过仪器和建模技术证明了其分析功效。我们的研究表明,硫化铁、碳酸铁和磷酸铁的无定形早期类似物可以在流动溶液之间的边界形成,在微观尺度上建模,并通过扫描电子显微镜/能量色散光谱、X 射线光电子能谱和拉曼光谱等标准仪器技术进行分析。
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Analysis of Early Iron Sulfide, Carbonate, and Phosphate Mineral Analogues Produced by Flow-Driven Precipitation in a Microchannel.

Most of the chemical and physical interactions of interest to the astrobiology community are influenced by the mineralogy of the systems under consideration. Often, this mineralogy occurs in sediment or sediment-like aqueous microenvironments in which the early minerals differ dramatically from the mature version that results from a long diagenesis, which are tied to complex interactions of pH, redox state, concentration, and temperature. This interconnectedness is difficult to reproduce in a laboratory setting yet is essential to understanding how the physical and chemical demands of living systems alter and are altered by their geological context. We present a facile means for producing precipitated mineral analogues within a microchannel and demonstrate its analytical efficacy through instrumental and modeling techniques. We show that amorphous, early-stage analogues of iron sulfide, iron carbonate, and iron phosphate can be formed at the boundary between flowing solutions, modeled on the microscale, and analyzed by standard instrumental techniques such as scanning electron microscopy/energy-dispersive spectroscopy, X-ray photoelectron spectroscopy, and Raman spectroscopy.

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来源期刊
Astrobiology
Astrobiology 生物-地球科学综合
CiteScore
7.70
自引率
11.90%
发文量
100
审稿时长
3 months
期刊介绍: Astrobiology is the most-cited peer-reviewed journal dedicated to the understanding of life''s origin, evolution, and distribution in the universe, with a focus on new findings and discoveries from interplanetary exploration and laboratory research. Astrobiology coverage includes: Astrophysics; Astropaleontology; Astroplanets; Bioastronomy; Cosmochemistry; Ecogenomics; Exobiology; Extremophiles; Geomicrobiology; Gravitational biology; Life detection technology; Meteoritics; Planetary geoscience; Planetary protection; Prebiotic chemistry; Space exploration technology; Terraforming
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