Critical Water Coverage during Forsterite Carbonation in Thin Water Films: Activating Dissolution and Mass Transport

In geologic carbon sequestration, CO is injected into geologic reservoirs as a supercritical fluid (scCO ). The carbonation of divalent silicates exposed to humidified scCO occurs in angstroms to nanometers thick adsorbed H O films. A threshold H O film thickness is required for carbonate precipitat...

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Bibliographic Details
Published in:Environmental science & technology 2020-06, Vol.54 (11), p.6888-6899
Main Authors: Placencia-Gómez, Edmundo, Kerisit, Sebastien N, Mehta, Hardeep S, Qafoku, Odeta, Thompson, Christopher J, Graham, Trent R, Ilton, Eugene S, Loring, John S
Format: Article
Language:English
Subjects:
Carbon dioxide
Carbon sequestration
Carbonation
Chemical precipitation
Computer simulation
Diffusion
Diffusion barriers
Dissolution
Electrical impedance
ENVIRONMENTAL SCIENCES
Film thickness
Forsterite
Free energy
Geology
Infrared reflection
Infrared spectroscopy
inorganic carbon compounds
ions
Magnesium
Magnesium carbonate
Mass transport
Molecular dynamics
monolayers
Permeability
precipitation
Silicates
Spectrum analysis
Supercritical fluids
Thick films
Thin films
Water film
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Summary:In geologic carbon sequestration, CO is injected into geologic reservoirs as a supercritical fluid (scCO ). The carbonation of divalent silicates exposed to humidified scCO occurs in angstroms to nanometers thick adsorbed H O films. A threshold H O film thickness is required for carbonate precipitation, but a mechanistic understanding is lacking. In this study, we investigated carbonation of forsterite (Mg SiO ) in humidified scCO (50 °C and 90 bar), which serves as a model system for understanding subsurface divalent silicate carbonation reactivity. Attenuated total reflection infrared spectroscopy pinpointed that magnesium carbonate precipitation begins at 1.5 monolayers of adsorbed H O. At about this same H O coverage, transmission infrared spectroscopy showed that forsterite dissolution begins and electrical impedance spectroscopy demonstrated that diffusive transport accelerates. Molecular dynamics simulations indicated that the onset of diffusion is due to an abrupt decrease in the free-energy barriers for lateral mobility of outer-spherically adsorbed Mg . The dissolution and mass transport controls on divalent silicate reactivity in wet scCO could be advantageous for maximizing permeability near the wellbore and minimize leakage through the caprock.
ISSN:0013-936X
1520-5851
DOI:10.1021/acs.est.0c00897