Glycine at the Pyrite−Water Interface:  The Role of Surface Defects

Ab initio molecular dynamics simulations were performed in order to study chemisorption, electronic properties, and desorption of glycine at wet pyrite surfaces focusing on the role of surface point defects. The change in the electronic structure and its influence on the chemical reactivity of the f...

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Bibliographic Details
Published in:Journal of the American Chemical Society 2006-10, Vol.128 (42), p.13815-13826
Main Authors: Nair, Nisanth N, Schreiner, Eduard, Marx, Dominik
Format: Article
Language:English
Subjects:
Chemistry
Exact sciences and technology
General and physical chemistry
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Summary:Ab initio molecular dynamics simulations were performed in order to study chemisorption, electronic properties, and desorption of glycine at wet pyrite surfaces focusing on the role of surface point defects. The change in the electronic structure and its influence on the chemical reactivity of the free FeS2(100) surface due to sulfur vacancies was studied in detail yielding several adsorption modes of glycine and water molecules. Energetically preferred adsorption modes were furthermore investigated in the presence of hot pressurized water mimicking “Iron Sulfur World” prebiotic conditions. The metadynamics Car−Parrinello technique was employed to map the free energy landscape including paths and barriers for desorption of glycine from such wet defective surfaces. The ubiquitous sulfur vacancies are found to increase the retention time of the adsorbed amino acid by many orders of magnitudes in comparison to the ideal pyrite−water interface. The importance of these findings in terms of a possible two-dimensional primordial chemistry on mineral surfaces is discussed.
ISSN:0002-7863
1520-5126
DOI:10.1021/ja063295a