The Role of Sulfuric Acid, Abiotic–Organic Acids, and Biotic Acids on Serpentinite Dissolution and Trace Metal Release

Organic acids produced by biota have been shown to accelerate the dissolution of minerals, possibly creating biosignatures in either reacting solutions or the solid materials. We tested aqueous alteration of serpentinite in three groups of solutions: inorganic acids, organic acids created through ab...

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Bibliographic Details
Published in:Minerals (Basel) 2024-02, Vol.14 (3), p.256
Main Authors: Taylor, Agnes R, Olsen, Amanda Albright, Hausrath, Elisabeth M, Olsen, Brian J, Cardace, Dawn
Format: Article
Language:English
Subjects:
Abiotic factors
aqueous alteration
Batch reactors
biosignatures
Biota
Carbon
Chemical properties
Chemistry
Composition
Constants
Dissolution
Dissolution (Chemistry)
Dissolving
Environmental aspects
Experiments
Heavy metals
Hydrocarbons
Inorganic acids
Ligands
Manganese
Mars
Meteors & meteorites
Microorganisms
Mineralogy
Minerals
Nitric acid
Nitric acids
Organic acids
Planetary systems
Precipitates
Serpentinite
Stability constants
Sulfuric acid
Sulphuric acid
Temperature
Trace elements
Trace metals
weathering
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Summary:Organic acids produced by biota have been shown to accelerate the dissolution of minerals, possibly creating biosignatures in either reacting solutions or the solid materials. We tested aqueous alteration of serpentinite in three groups of solutions: inorganic acids, organic acids created through abiotic processes (termed “abiotic–organics”), and organic acids created through biotic processes (termed “biotic acids”) over a range of temperatures relevant to conditions on Mars and Europa. A total of 48 batch reactor experiments were carried out at 0 °C, 22 °C, and 62 °C in 16 different acids at pH 2.6 over 28 days. Additional experiments were conducted in sulfuric acid solutions to assess aqueous alteration in sulfate-rich environments. These results show that biotic acids accelerate serpentinite dissolution compared to the control inorganic acid, whereas abiotic–organic acids have little or no effect. Sulfuric acid enhances serpentinite dissolution over nitric acid. Secondary precipitates found in the presence of biotic acids were consistently enhanced in Mn, Ti, and W. We propose that these preferentially released elements and secondary minerals may be potential biosignatures. We also show that the release of the rock-forming elements Mg and Si is correlated with stability constants for the metal–acid aqueous complex, providing a possible mechanistic interpretation of the observed results.
ISSN:2075-163X
2075-163X
DOI:10.3390/min14030256