A reaction-diffusion model for the hydration of calciumsulphate (gypsum) and microstructure percolation
Abstract
We have numerically investigated a reaction-diffusion model for the hydration of calciumsulphate (gypsum). The simulations were conducted for two and three dimensional systems. While the dissolution of anhydrous gypsum is considered irreversible at a finite rate the precipitation/dissolution reaction for the calciumdihydrate is considered reversible. The latter reaction is assumed to be controlled by the dihydrate's equilibrium solubility and the abillity of the system to react on supersaturation only at a certain velocity described by the reaction rate constant of precipitation. For d=2 we find at early times an accelerated hydration period followed by a maximum and a decreasing hydration rate. For large times the ionic product of involved species assumes closely the value of the di-hydrate equilibrium solubility. Calculated model micro-structures exhibit typical features such as inner and outer hydrate products, induction and dormant period as well as bridging. Furthermore we find that the overall chemical reactivity as a function of initial anhydrous (volume) concentration p exhibits a maximum close to the percolation point of the underlying lattice. Employing a rescaling procedure we find two percolation thresholds in d=2, pcmin=0.44 0.015 and pcmax=0.77 0.02, for the initial anhydrous gypsum concentration between which percolating dihydrate structures can be attained. For d=3 we find pcmin=0.10 0.02 and pcmax=0.95 0.02.
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