Abstract
HypothesisSilanol groups at the silica–water interface determine not only the surface charge, but also have an important role in the binding of ions and biomolecules. As the pH is increased above pH 2, the silica surface develops a net negative charge primarily due to deprotonation of the silanol group. An improved understanding of the energetics and mechanisms of this fundamentally important process would further understanding of the relevant dynamics. SimulationsDensity Functional Theory ab initio molecular dynamics and geometry optimisations were used to investigate the mechanisms of surface neutralisation and charging in the presence of OH- and H3O+ respectively. This charging mechanism has received little attention in the literature. FindingsThe protonation or deprotonation of isolated silanols in the presence of H3O+ or OH-, respectively, was shown to be a highly rapid, exothermic reaction with no significant activation energy. This process occurred via a concerted motion of the protons through ‘water wires’. Geometry optimisations of large water clusters at the silica surface demonstrated proton transfer to the surface occurring via the rarely discussed ‘proton holes’ mechanism. This indicates that surface protonation is possible even when the hydronium ion is distant (at least 4 water molecules separation) from the surface.
Highlights
Silica and water represent two of the most abundant chemical systems, and it is unsurprising that understanding the interface between them is relevant to a wide variety of systems
In order to investigate the proton transfer described in Eq (1), 200 fs of Ab initio molecular dynamics (AIMD) were performed on the Silicon surface atoms (Ssurf) OÀ þ H3Oþ system
Both the geometry optimisation and the AIMD simulation showed a proton transfer from the H3Oþ to the Si À OÀ resulting in a Si À OH . . . H2O hydrogen bonded system, as described in Eq (1)
Summary
Silica and water represent two of the most abundant chemical systems, and it is unsurprising that understanding the interface between them is relevant to a wide variety of systems. B.M. Lowe et al / Journal of Colloid and Interface Science 451 (2015) 231–244 as dissolution rates [1,2,3] and the surface adsorption of ions and molecules [4,5]. Chemical reactions of reactive silanol groups ðSi—OHÞ with Hþ=OHÀ are thought to be the primary surface charging mechanism for silica [6], with electrolyte effects having a measurable but less significant effect [7]
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