利用微X射线调查风化环境中的微生物生物特征:模拟 "毅力 "2020 火星漫游车搭载的 PIXL 仪器在杰泽罗环形山的分析。

IF 3.5 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS
Astrobiology Pub Date : 2024-05-01 DOI:10.1089/ast.2022.0031
Marion Nachon, Ryan C Ewing, Michael M Tice, Blake Williford, Nadejda Marounina
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引用次数: 0

摘要

评估火星过去的宜居性以及通过毅力号漫游车在杰泽罗陨石坑寻找远古生命的证据是美国国家航空航天局(NASA)2020 年火星任务的关键目标。漫游车上的 PIXL(X 射线岩石化学行星仪器)是最适合寻找微生物生物特征的仪器之一,因为它能够利用无损技术表征地质目标中细微纹理的化学成分。PIXL 还是第一台搭载在火星探测器上的微型 X 射线荧光 (XRF) 光谱仪。在此,我们介绍了利用 PIXL 类似的微 XRF(μXRF)分析来识别和研究风化环境中微生物生物特征的指南。我们从得克萨斯州帕德里岛的现代潮湿风化环境中采集了含有埋藏微生物垫的样本,并使用类似于火星上 PIXL 运行方式的 μXRF 技术对其进行了分析。我们通过 μXRF 技术和显微镜图像展示了从地表到 40 厘米深处的地球化学和纹理变化。微生物垫与重矿物滞后有关,并显示出特定的纹理和地球化学特征,使其成为该环境的独特生物特征。在埋藏过程中,由于充满气体的空隙的膨胀和收缩,它们获得了弥散的纹理,并且由于重矿物的捕获,它们呈现出富含铁和钛的地球化学特征。我们的研究表明,这些固有特征可以通过μXRF分析检测到,而且它们有别于交叉层理和粘附波纹层理等埋藏的非生物面貌。我们还利用帕德里岛的 μXRF 数据设计并开展了一项互动调查,以探索不同用户如何选择通过类似 PIXL 的取样策略来调查含生物特征的数据集。我们发现,通过类似 PIXL 的分析方法调查生物特征在很大程度上受到技术限制(如 XRF 测量特性)和不同科学家选择的各种方法的影响。在漫游者任务限制条件下准确识别和描述这种生物特征的经验教训包括:确定测量的相对优先级,在 XRF 测量选择的决策过程中倾向于采用多学科方法,以及考虑非生物结果以支持或放弃生物特征解释。我们的研究结果为火星上潜在生物特征的 PIXL 分析提供了指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Investigating Microbial Biosignatures in Aeolian Environments Using Micro-X-Ray: Simulation of PIXL Instrument Analyses at Jezero Crater Onboard the Perseverance Mars 2020 Rover.

Assessing the past habitability of Mars and searching for evidence of ancient life at Jezero crater via the Perseverance rover are the key objectives of NASA's Mars 2020 mission. Onboard the rover, PIXL (Planetary Instrument for X-ray Lithochemistry) is one of the best suited instruments to search for microbial biosignatures due to its ability to characterize chemical composition of fine scale textures in geological targets using a nondestructive technique. PIXL is also the first micro-X-ray fluorescence (XRF) spectrometer onboard a Mars rover. Here, we present guidelines for identifying and investigating a microbial biosignature in an aeolian environment using PIXL-analogous micro-XRF (μXRF) analyses. We collected samples from a modern wet aeolian environment at Padre Island, Texas, that contain buried microbial mats, and we analyzed them using μXRF techniques analogous to how PIXL is being operated on Mars. We show via μXRF technique and microscope images the geochemical and textural variations from the surface to ∼40 cm depth. Microbial mats are associated with heavy-mineral lags and show specific textural and geochemical characteristics that make them a distinct biosignature for this environment. Upon burial, they acquire a diffuse texture due to the expansion and contraction of gas-filled voids, and they present a geochemical signature rich in iron and titanium, which is due to the trapping of heavy minerals. We show that these intrinsic characteristics can be detected via μXRF analyses, and that they are distinct from buried abiotic facies such as cross-stratification and adhesion ripple laminations. We also designed and conducted an interactive survey using the Padre Island μXRF data to explore how different users chose to investigate a biosignature-bearing dataset via PIXL-like sampling strategies. We show that investigating biosignatures via PIXL-like analyses is heavily influenced by technical constraints (e.g., the XRF measurement characteristics) and by the variety of approaches chosen by different scientists. Lessons learned for accurately identifying and characterizing this biosignature in the context of rover-mission constraints include defining relative priorities among measurements, favoring a multidisciplinary approach to the decision-making process of XRF measurements selection, and considering abiotic results to support or discard a biosignature interpretation. Our results provide guidelines for PIXL analyses of potential biosignature on Mars.

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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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