Non-isothermal decomposition kinetics of nano-scale CaCO3 as a function of particle size variation

We report the synthesis of nanocrystalline calcium carbonate with varying particle sizes by precipitation techniques from an aqueous solution of calcium nitrate and sodium carbonate at controlled pH. The particle size of the carbonate powder was precisely controlled by changing the precursor concentration. The synthesized carbonate powders were characterized by using scanning electron microscopy, X-ray diffraction technique, and transmission electron microscopy. The particle size, along with the crystallite size of as-synthesized carbonate powder, decreases with increasing precursor concentration. The non-isothermal decomposition kinetics of the carbonate powder was also evaluated by using near to the modified Arrhenius equation's exact solution. The experimental results were best fitted at n = 0.5, and the one-dimensional diffusion-controlled transport process mechanism (D-1) and one-dimensional phase boundary movement mechanism (R-1) was found to be very close fit of the corresponding evaluated g(alpha) value. The apparent activation energy of the nano calcium carbonate decomposition was found in the range of 120-175 kJ/mol, which is also inherently functioning with the average particle size. The apparent activation energy of decomposition of CaCO3 found to be decreased with decreasing average particle size of nanocrystalline calcium carbonate.

Automated summary

Nanocrystalline calcium carbonate with varying particle sizes was successfully synthesized using precipitation techniques from an aqueous solution at controlled pH. The particle size and crystallite size could be precisely controlled by changing the precursor concentration, and the apparent activation energy of decomposition decreased with decreasing average particle size of nanocrystalline calcium carbonate.