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- Title
Microdroplets initiate organic-inorganic interactions and mass transfer in thermal hydrous geosystems.
- Authors
Yuan, Guanghui; Jin, Zihao; Cao, Yingchang; Schulz, Hans-Martin; Gluyas, Jon; Liu, Keyu; He, Xingliang; Wang, Yanzhong
- Abstract
Organic-inorganic interactions regulate the dynamics of hydrocarbons, water, minerals, CO2, and H2 in thermal rocks, yet their initiation remains debated. To address this, we conducted isotope-tagged and in-situ visual thermal experiments. Isotope-tagged studies revealed extensive H/O transfers in hydrous n-C20H42-H2O-feldspar systems. Visual experiments observed water microdroplets forming at 150–165 °C in oil phases near the water-oil interface without surfactants, persisting until complete miscibility above 350 °C. Electron paramagnetic resonance (EPR) detected hydroxyl free radicals concurrent with microdroplet formation. Here we propose a two-fold mechanism: water-derived and n-C20H42-derived free radicals drive interactions with organic species, while water-derived and mineral-derived ions trigger mineral interactions. These processes, facilitated by microdroplets and bulk water, blur boundaries between organic and inorganic species, enabling extensive interactions and mass transfer. Our findings redefine microscopic interplays between organic and inorganic components, offering insights into diagenetic and hydrous-metamorphic processes, and mass transfer cycles in deep basins and subduction zones. At elevated temperatures, water microdroplets emerge near oil-water interfaces, functioning as tiny geochemical reactors that initiate interactions and mass transfer among organic and inorganic components in thermal geosystems.
- Subjects
MASS transfer; MICRODROPLETS; HEAT transfer; ELECTRON paramagnetic resonance; HYDROUS; MISCIBILITY
- Publication
Nature Communications, 2024, Vol 15, Issue 1, p1
- ISSN
2041-1723
- Publication type
Article
- DOI
10.1038/s41467-024-49293-y