Fully hydroxylated surfaces derived from crystalline edingtonite were adopted to model the variety of sites known to exist at the amorphous silica surface, namely isolated, geminal and interacting silanols. Structures, energetics and vibrational features of the surfaces either bare or in contact with water were modelled at DFT level using the B3LYP functional with a GTO basis set of double-zeta polarized quality using the periodic ab-initio CRYSTAL06 code. Simulated infrared spectra of both dry and water wet edingtonite surfaces were in excellent agreement with the experimental ones recorded on amorphous silica. Water interaction energies were compared with microcalorimetric differential heats of adsorption data showing good agreement, albeit computed ones being slightly underestimated due to the lack of dispersive forces in the B3LYP functional.

Hydroxylated crystalline edingtonite silica faces as models for the amorphous silica surface

CIVALLERI, Bartolomeo;UGLIENGO, Piero
2008-01-01

Abstract

Fully hydroxylated surfaces derived from crystalline edingtonite were adopted to model the variety of sites known to exist at the amorphous silica surface, namely isolated, geminal and interacting silanols. Structures, energetics and vibrational features of the surfaces either bare or in contact with water were modelled at DFT level using the B3LYP functional with a GTO basis set of double-zeta polarized quality using the periodic ab-initio CRYSTAL06 code. Simulated infrared spectra of both dry and water wet edingtonite surfaces were in excellent agreement with the experimental ones recorded on amorphous silica. Water interaction energies were compared with microcalorimetric differential heats of adsorption data showing good agreement, albeit computed ones being slightly underestimated due to the lack of dispersive forces in the B3LYP functional.
2008
Ab initio Simulation of Crystalline Solids: History and Prospects
Torino
8-9 Settembre 2007
117
012026
012034
http://www.iop.org/EJ/abstract/1742-6596/117/1/012026
AMORPHOUS SILICA SURFACE; water adsorption
S. Tosoni; B. Civalleri; F. Pascale; P. Ugliengo
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2318/60122
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