TY - JOUR
T1 - Trimethylethoxysilane Liquid-Phase Hydrolysis Equilibrium and Dimerization Kinetics
T2 - Catalyst, Nonideal Mixing, and the Condensation Route
AU - Rankin, Stephen E.
AU - Šefčík, Ján
AU - McCormick, Alon V.
PY - 1999/5/27
Y1 - 1999/5/27
N2 - Although the kinetics of organoethoxysilane hydrolytic (poly)condensation have been studied under kinetically simplified conditions, materials are actually synthesized from nonideal mixtures with high monomer and catalyst concentrations. Using 29Si nuclear magnetic resonance, we study the hydrolysis of trimethylethoxysilane and the dimerization of the resulting silanol in aqueous ethanol at monomer and catalyst concentrations typical of organically modified silicate synthesis. Under acidic conditions, we find that when (and only when) the effects of solvent composition on catalyst activity are considered, it becomes clear that water-producing condensation is the dominant dimerization route. Under basic conditions, the extent of deprotonation of the weakly acidic silanol passes through a minimum during reaction, thereby producing an anomolous trend in reaction rate. This necessitates a kinetic model which is first order in both silanol and deprotonated silanol and which accounts for changing deprotonation.
AB - Although the kinetics of organoethoxysilane hydrolytic (poly)condensation have been studied under kinetically simplified conditions, materials are actually synthesized from nonideal mixtures with high monomer and catalyst concentrations. Using 29Si nuclear magnetic resonance, we study the hydrolysis of trimethylethoxysilane and the dimerization of the resulting silanol in aqueous ethanol at monomer and catalyst concentrations typical of organically modified silicate synthesis. Under acidic conditions, we find that when (and only when) the effects of solvent composition on catalyst activity are considered, it becomes clear that water-producing condensation is the dominant dimerization route. Under basic conditions, the extent of deprotonation of the weakly acidic silanol passes through a minimum during reaction, thereby producing an anomolous trend in reaction rate. This necessitates a kinetic model which is first order in both silanol and deprotonated silanol and which accounts for changing deprotonation.
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U2 - 10.1021/jp990304b
DO - 10.1021/jp990304b
M3 - Article
AN - SCOPUS:0000217467
SN - 1089-5639
VL - 103
SP - 4233
EP - 4241
JO - Journal of Physical Chemistry A
JF - Journal of Physical Chemistry A
IS - 21
ER -