Interfacial water on crystalline silica: a comparative molecular dynamics simulation study

Ho, Tuan A.; Argyris, Dimitrios; Papavassiliou, Dimitrios V.; Striolo, Alberto; Lee, Lloyd L.; Cole, David R.

doi:10.1080/08927022.2010.513008

Title: Interfacial water on crystalline silica: a comparative molecular dynamics simulation study

Journal Article · Thu Mar 03 00:00:00 EST 2011 · Molecular Simulation

DOI:https://doi.org/10.1080/08927022.2010.513008· OSTI ID:1045871

Ho, Tuan A. ^[1]; Argyris, Dimitrios ^[1]; Papavassiliou, Dimitrios V. ^[1]; Striolo, Alberto ^[1]; Lee, Lloyd L. ^[2]; Cole, David R. ^[3]

Univ. of Oklahoma, Norman, OK (United States)
California State Polytechnic Univ., Pomona, CA (United States)
The Ohio State Univ., Columbus, OH (United States)

All-atom molecular dynamics simulations were conducted to study the dynamics of aqueous electrolyte solutions confined in slit-shaped silica nanopores of various degrees of protonation. Five degrees of protonation were prepared by randomly removing surface hydrogen atoms from fully protonated crystalline silica surfaces. Aqueous electrolyte solutions containing NaCl or CsCl salt were simulated at ambient conditions. In all cases, the ionic concentration was 1 M. The results were quantified in terms of atomic density distributions within the pores, and the self-diffusion coefficient along the direction parallel to the pore surface. We found evidence for ion-specific properties that depend on ion surface, water ion, and only in some cases ion ion correlations. The degree of protonation strongly affects the structure, distribution, and the dynamic behavior of confined water and electrolytes. Cl ions adsorb on the surface at large degrees of protonation, and their behavior does not depend significantly on the cation type (either Na+ or Cs+ ions are present in the systems considered). The cations show significant ion-specific behavior. Na+ ions occupy different positions within the pore as the degree of protonation changes, while Cs+ ions mainly remain near the pore center at all conditions considered. For a given degree of protonation, the planar self-diffusion coefficient of Cs+ is always greater than that of Na+ ions. The results are useful for better understanding transport under confinement, including brine behavior in the subsurface, with important applications such as environmental remediation.

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Research Organization:: Oak Ridge National Lab. (ORNL), Oak Ridge, TN (United States)

Sponsoring Organization:: USDOE Office of Science (SC)

DOE Contract Number:: AC05-00OR22725

OSTI ID:: 1045871

Journal Information:: Molecular Simulation, Vol. 37, Issue 3; ISSN 0892-7022

Publisher:: Taylor & Francis

Country of Publication:: United States

Language:: English

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74 ATOMIC AND MOLECULAR PHYSICS
molecular dynamics
atomistic
force-field effects

Title: Interfacial water on crystalline silica: a comparative molecular dynamics simulation study

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