Abstract
The adsorption of nucleic acid components onto the serpentinite-hosted hydrothermal mineral brucite has been
investigated experimentally by determining the equilibrium adsorption isotherms in aqueous solution. Ther
modynamic characterization of the adsorption data has been performed using the extended triple-layer model
(ETLM) to establish a model for the stoichiometry and equilibrium constants of surface complexes. Infrared
characterization of the molecule–mineral complexes has helped gain insight into the molecular functional
groups directly interacting with the mineral surface. Quantum mechanical calculations have been carried out to
identify the possible complexes formed on surfaces by nucleic acid components and their binding configurations
on mineral surfaces, both in the presence of water molecules and in water-free conditions. The results indicate
that brucite favors adsorption of nucleotides with respect to nucleosides and nucleobases from dilute aqueous
environments. The surface of this mineral is able to induce well-defined orientations of the molecules through
specific molecule–mineral interactions. This result suggests plausible roles of the mineral brucite in assisting
prebiotic molecular self-organization. Furthermore, the detection of the infrared spectroscopic features of such
building blocks of life adsorbed on brucite at very low degrees of coverage provides important support to life
detection investigations. Key Words: Molecule–mineral interactions—Nucleic acid components—Brucite—
Adsorption—Infrared spectroscopy.
Lingua originale | Inglese |
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pagine (da-a) | 989-1007 |
Numero di pagine | 19 |
Rivista | Astrobiology |
Volume | 18 |
Numero di pubblicazione | 8 |
DOI | |
Stato di pubblicazione | Pubblicato - 2018 |