The crucial role of molecular emissions on LIBS differentiation of organic compounds of interest in astrobiology under a Mars simulated atmosphere

In this work, the influence of Martian atmosphere on the recombination mechanisms in laser-induced plasmas of organic compounds of interest in astrobiology has been closely examined. The proposed LIBS methodology reveals new insights concerning the influence of the surrounding atmosphere on the mole...

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Published inSpectrochimica acta. Part B: Atomic spectroscopy Vol. 192; p. 106413
Main Authors Delgado, T., Fortes, F.J., Cabalín, L.M., Laserna, J.J.
Format Journal Article
LanguageEnglish
Published Oxford Elsevier B.V 01.06.2022
Elsevier BV
Subjects
Algorithms
Astrobiology
Atmospheric pressure
Biomarkers
Differentiation
Discriminant analysis
Discriminant function analysis
Emissions
Emitters
Feasibility
Laser plasmas
Lasers
LIBS
Low pressure
Mars
Mars atmosphere
Mars environment
Martian atmosphere
Molecular emission
Organic compounds
Plasma chemistry
Plasmas (physics)
Recombination
Statistical analysis
Statistical methods
Martian atmosphere
Discriminant function analysis
LIBS
Molecular emission
Organic compounds
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Summary:In this work, the influence of Martian atmosphere on the recombination mechanisms in laser-induced plasmas of organic compounds of interest in astrobiology has been closely examined. The proposed LIBS methodology reveals new insights concerning the influence of the surrounding atmosphere on the molecular emission of organics. The presence of nitrogen, even in the short concentration found in the low-pressure Mars environment, influences the plasma chemistry and the formation pathways leading to molecular species. Characteristic atomic and molecular emitters (C, H, C2, CN, NH, OH and CH) were inspected in a set of selected organic compounds considered as meaningful biomarkers. For comparative purposes, LIBS analysis was performed in both low-pressure air and Martian atmospheres. Statistical analysis (linear discriminant analysis; DFA) suggested that satisfactory differentiation among materials was feasible under Martian conditions when molecular emissions are computed in the classification algorithm. Atomic lines (C, H) only contribute a mere ~62% to the discriminating analysis, whereas the percentage of successful discrimination was considerably increased (up to 99%) by the progressive introduction of signals associated to molecular bands into the DFA analysis, thus confirming the major contribution of molecular information to the final sorting performance and the feasibility of discriminating closely related organic compounds by LIBS in the Martian atmosphere. [Display omitted] •Martian atmosphere affects the formation pathways leading to molecular emission species.•LIBS assisted by DFA offers a practical tool for identification of organic biosignatures.•Sorting of organics in groups requires both molecular and atomic LIBS signals inputs.
ISSN:0584-8547
1873-3565
DOI:10.1016/j.sab.2022.106413