Precipitated silica

About: Precipitated silica is a research topic. Over the lifetime, 1401 publications have been published within this topic receiving 20992 citations.

Reinforcement of maleated natural rubber by precipitated silica

Abstract: Graft copolymers of maleic anhydride and natural rubber or so-called maleated natural rubbers (MNRs) were prepared in a molten state with varying maleic anhydride contents from 4 to 10 phr. In this work, the filler–filler and filler–rubber interactions of the MNR and precipitated silica were investigated. The MNR compounds containing 40 phr of silica both with and without 9 wt % of silane coupling agent were prepared. By increasing the maleic anhydride contents, the Mooney viscosity and cure times were increased, but the torque differences and cure rate indices were decreased. Bound rubber was increased with increasing maleic anhydride content, indicating an increase of filler–rubber interaction. In case of the compounds without silane, the MNR with 6 phr of maleic anhydride showed the lowest filler–filler interaction as indicated by a decrease of storage modulus upon an increase of strain in the filled compound i.e., Payne effect. This MNR compound also yielded the optimum mechanical properties. It has been demonstrated that a use of MNR with appropriate maleic anhydride content can reduce filler–filler interaction dramatically and hence improve a silica dispersion, as confirmed by SEM micrographs, resulting in an enhancement of the mechanical and dynamical properties. © 2008 Wiley Periodicals, Inc. J Appl Polym Sci, 2008

Silicification and biosilicification - Part 7: Poly-L-arginine mediated bioinspired synthesis of silica

Abstract: Precipitated silica is synthesized commercially by neutralizing sodium silicate solution under harsh conditions of pH and temperature. In contrast, the formation of ornate silica structures in biological systems (biosilicification) occurs at (or close to) pH 7 under ambient conditions and is thought to be mediated by proteins. Determination of the primary sequences of these proteins has led to the identification of various amino acids that have been proposed to be important in biosilicification. The corresponding synthetic polyamino acids are now being successfully used in bioinspired materials chemistry for developing new materials and processes. Here we report the formation of well-defined silica in vitro as facilitated by poly-L-arginine (PLAr) under ambient conditions and at neutral pH. Two different silica precursors were used in this investigation; tetramethoxysilane (TMOS) and water glass. Scanning Electron Microscopy (SEM) was used for studying the silica morphology and it was revealed that the silica spheres had typical diameters in the range 300–500nm. The PLAr is a cationically charged macromolecule at neutral pH and is believed to act as a catalyst/template/scaffold for the formation of silica in vitro in analogous fashion to certain biomacromolecules that are able to facilitate silicification/biosilicification. These results are discussed here in the context of the role(s) of (bio)macromolecules that facilitate (bio)mineralization.