Specific Cation Effects on the Bimodal Acid–Base Behavior of the Silica/Water Interface

Using nonresonant second harmonic generation spectroscopy, we have monitored the change in surface charge density of the silica/water interface over a broad pH range in the presence of different alkali chlorides. Planar silica is known to possess two types of surface sites with pK a values of ∼4 and...

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Bibliographic Details
Published in:The journal of physical chemistry letters 2012-05, Vol.3 (10), p.1269-1274
Main Authors: Azam, Md. Shafiul, Weeraman, Champika N, Gibbs-Davis, Julianne M
Format: Article
Language:English
Subjects:
Surfaces, Interfaces, Porous Materials, and Catalysis
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Summary:Using nonresonant second harmonic generation spectroscopy, we have monitored the change in surface charge density of the silica/water interface over a broad pH range in the presence of different alkali chlorides. Planar silica is known to possess two types of surface sites with pK a values of ∼4 and ∼9, which are attributed to different solvation environments of the silanols. We report that varying the alkali chloride electrolyte significantly changes the effective acid dissociation constant (pK a eff) for the less acidic silanol groups, with the silica/NaClaq and silica/CsClaq interfaces exhibiting the lowest and highest pK a eff values of 8.3(1) and 10.8(1), respectively. Additionally, the relative populations of the two silanol groups are also very sensitive to the electrolyte identity. The greatest percentage of acidic silanol groups was 60(2)% for the silica/LiClaq interface in contrast to the lowest value of 20(2)% for the silica/NaClaq interface. We attribute these changes in the bimodal behavior to the influence of alkali ions on the interfacial water structure and its corresponding effect on surface acidity.
ISSN:1948-7185
1948-7185
DOI:10.1021/jz300255x