E. Rivera-Munoz (1), W. Brostow (1,2), R. Rodriguez (1), V. M. Castano (1,2)

(1) Instituto de Fisica, Universidad Nacional Autonoma de Mexico, Apdo. Postal 1-1010, Quertaro, 76000, Mexico
(2) Department of Materials Science and Chemistry, University of North Texas, Denton, TX 76203-5310, USA

ABSTRACT

Synthetic hydroxiapatite was grown on surfaces of silica gels by immersing silica monoliths in a simulated body fluid at 37 C. The gels were prepared by the sol-gel method and the drying process was controlled by using different additives (mono- and di-ethylene glycol, formamide and glycerin) to obtain large monoliths. The additives affect the growth of the apatite by changing the kinetic constants of chemical reactions on the silica surface. Surface areas and pore size distributions were determined, energy dispersion and FTIR spectra obtained, and scanning electron microscopy performed. The formation of the hydroxiapatite competes with the formation of crystalline calcium carbonate, but the results allow optimization of conditions for the growth of the former as a function of the type and concentration of the additive. For these optimal conditions, the mechanism and the order of the reaction were determined.