Synthesis of Silica Nano and
Micro Structures at Neutral pH and Under Ambient Conditions: Effects and Role
of Macromolecules With an Example of a Cationically Charged Synthetic Polymer
Siddharth Patwardhan
MS, January 2002
ABSTRACT
The synthesis of silica particles by sol-gel
processing and the chemistry of colloidal silica are well known. With the
recent advents in the silicification process, at neutral pH and under modest
conditions in diatoms it is interesting to develop an economical process using
the above-mentioned results and understand the mechanism and the role of
macromolecules in the process in vivo
and in vitro.
To verify the specificity of polypeptides in
silicification and to attempt commercialization of silica synthesis at neutral
pH and under modest conditions, poly(allylamine hydrochloride) (PAH), a
cationically charged synthetic polymer was used in this research. PAH is
predicted to form hydrogen and ionic bonds with the intermediate negatively
charged growing species of the silica sol. To avoid the use of TEOS due to
solubility problems and slower kinetics, only tetramethoxysilane (TMOS) was
used throughout as the silica precursor. Dependence of silicification on
following process parameters is studied: TMOS pre-hydrolysis time (tP),
reaction time (tR), type of buffer used, molar mass of polymer,
polymer concentration (Cp), TMOS concentration, density and
molecular environment of active sites on the polymer, and perturbation of the
reaction mixture during the course of the reaction.
It was found that the TMOS pre-hydrolysis time was an important parameter governing the resulting silica morphology along with the reaction time and the TMOS concentration. Characterization was performed using SEM, FTIR, EDS and XRD. The PAH, which acts as a catalyst / template, was found to be incorporated into the silica particles. The synthesis of elongated silica chains / rods of the nanometer size scale formed by the orientation of a growing silica sol is also reported. The system was perturbed by externally applied shear. It is proposed that the polymer orientation plays an important role in the formation of such morphologies.
It is also proposed here that, using the results of
the SCCO2 polymerizations and stabilization of water – SCCO2
(W/C) emulsions, silica particles can be synthesized in W/C emulsions. In this
way, we achieve controlled synthesis of silica particles by controlling the
size of the emulsion. In additions, we can encapsulate water-soluble material
in a silica shell.
Key Words: Silica, silicification, biosilica, poly(allylamine hydrochloride) (PAH), tetramethoxysilane (TMOS), sol-gel, supercritical carbon dioxide.