Molecular dynamics simulations of anion exclusion in clay interlayer nanopores.

Christophe Tournassat 1, 2, 3 Ian C. Bourg 4, 5 Michael Holmboe 6 Garrison Sposito 4, 5 Carl I. Steefel 5
1 ISTO - Institut des Sciences de la Terre d'Orléans - UMR7327
2 BRGM - Bureau de Recherches Géologiques et Minières (BRGM)
3 Milieux Poreux - UMR7327
ISTO - Institut des Sciences de la Terre d'Orléans - UMR7327 : UMR7327
4 Princeton University
5 LBNL - Lawrence Berkeley National Laboratory [Berkeley]
6 Umeå University
Abstract : The aqueous chemistry of water films confined between clay mineral surfaces remains an important unknown in predictions of radioelement migration from radioactive waste repositories. This issue is particularly important in the case of long-lived anionic radioisotopes Embedded Image which interact with clay minerals primarily by anion exclusion. For example, models of ion migration in clayey media do not agree as to whether anions are completely or partially excluded from clay interlayer nanopores. In the present study, this key issue was addressed for Cl− using MD simulations for a range of nanopore widths (6 to 15 Å) overlapping the range of average pore widths that exists in engineered clay barriers. The MD simulation results were compared with the predictions of a thermodynamic model (Donnan Equilibrium model) and two pore-scale models based on the Poisson-Boltzmann equation under the assumption that interlayer water behaves as bulk liquid water. The simulations confirmed that anion exclusion from clay interlayers is greater than predicted by the pore-scale models, particularly at the smallest pore size examined. This greater anion exclusion stems from Cl− being more weakly solvated in nano-confined water than it is in bulk liquid water. Anion exclusion predictions based on the Poisson-Boltzmann equation were consistent with the MD simulation results, however, if the predictions included an ion closest approach distance to the clay mineral surface on the order of 2.0 ± 0.8 Å. These findings suggest that clay interlayers approach a state of complete anion exclusion (hence, ideal semi-permeable membrane properties) at a pore width of 4.2 ± 1.5 Å.
Keywords : Semi-Permeable Membrane Poisson-Boltzmann Nanopores Molecular Dynamics Interlayer Donnan Equilibrium Model Clay Anion Exclusion
Document type :
Journal articles
Complete list of metadatas

Cited literature [77 references]  Display  Hide  Download
https://hal-insu.archives-ouvertes.fr/insu-01406301
Contributor : Nathalie Pothier <>
Submitted on : Thursday, May 11, 2017 - 10:03:34 AM
Last modification on : Friday, May 10, 2019 - 1:54:18 PM
Long-term archiving on : Saturday, August 12, 2017 - 12:44:18 PM

File

Tournassat-Clays&ClayMinerals-...
Publication funded by an institution

Identifiers

Collections

INSU | ISTO | OSUC | UNIV-ORLEANS | BRGM | PSL | OBSPM

Citation

Christophe Tournassat, Ian C. Bourg, Michael Holmboe, Garrison Sposito, Carl I. Steefel. Molecular dynamics simulations of anion exclusion in clay interlayer nanopores.. Clays and Clay Minerals, Clay Minerals Society, 2016, 4, pp.374-388. ⟨10.1346/CCMN.2016.0640403⟩. ⟨insu-01406301⟩

Export

BibTeX TEI DC DCterms EndNote

Share

Metrics

Record views

225

Files downloads

217

Contact

support.ccsd.cnrs.fr
hal.support@ccsd.cnrs.fr
Logo CCSD