Tetraethyl orthosilicate

Applications

TEOS is mainly used as a crosslinking agent in silicone polymers and as a precursor to silicon dioxide in the semiconductor industry.

TEOS is also used as the silica source for synthesis of some zeolites. Other applications include coatings for carpets and other objects. TEOS is used in the production of aerogel. These applications exploit the reactivity of the Si-OR bonds. TEOS has historically been used as an additive to alcohol based rocket fuels to decrease the heat flux to the chamber wall of regeneratively cooled engines by over 50%.

TEOS is used in steel casting industry as an inorganic binder and stiffener for making silica-based ceramic molding forms (see also sodium silicate). and as an inorganic binder for coatings (passivation) of different materials such as steel, glass, brass, and wood in order to make surfaces resistant to water, oxygen and high temperatures.. Further applications of TEOS include its use as an additive to solid polymers to enhance their adhesion to glass, steel or wood, as a binder for porcelain teeth crowns, and as a precursor to siloxanes.

Other reactions

TEOS easily converts to silicon dioxide upon the addition of water: : An idealized equation is shown, in reality the silica produced is hydrated. This hydrolysis reaction is an example of a sol-gel process. The side product is ethanol. The reaction proceeds via a series of condensation reactions that convert the TEOS molecule into a mineral-like solid via the formation of Si-O-Si linkages. Rates of this conversion are sensitive to the presence of acids and bases, both of which serve as catalysts. The Stöber process allows the formation of monodisperse and mesoporous silica.

At elevated temperatures (600 °C), TEOS converts to silicon dioxide: : The volatile coproduct is diethyl ether.

Safety

Inhalation of TEOS induces eye and nose irritation, and eye contact with the liquid is irritating. High exposure to TEOS can lead to pulmonary edema, but hazards can be reduced by atmospheric humidity and vapor pressure conditions. The mechanism of irritation is similar to that of tetramethyl orthosilicate.

References

References

1. {{PGCH. 0282
2. {{IDLH. 78104. Ethyl silicate
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