Reactive CaCO3 Formation from CO2 and Methanolic Ca(OH)2 Dispersions: Transient Methoxide Salts, Carbonate Esters and Sol–Gels

A combination of ex situ and in situ characterization techniques was used to determine the mechanism of calcium carbonate (CaCO₃) formation from calcium hydroxide (Ca(OH)₂) dispersions in methanol/water (CH₃OH/H₂O) systems. Mid-infrared (mid-IR) analysis shows that in the absence of carbon dioxide (CO₂) Ca(OH)₂ establishes a reaction equilibrium with CH₃OH, forming calcium hydroxide methoxide (Ca(OH)(OCH₃)) and calcium methoxide (Ca(OCH₃)₂). Combined ex situ mid-IR, thermogravimetric analysis (TGA), X-ray diffraction (XRD), X-ray absorption spectroscopy and scanning electron microscopy examination of the reaction product formed in the presence of CO₂ reveals the formation of calcium dimethylcarbonate (Ca(OCOOCH₃)₂). This strongly suggests that carbonation takes place by reaction with the Ca(OCH₃)₂ formed from a Ca(OH)₂ and CH₃OH reaction. Time-resolved XRD indicates that in the presence of H₂O the Ca(OCOOCH₃)₂ ester releases CH₃OH and CO₂, forming ACC, which subsequently transforms into vaterite and then calcite. TGA reveals that thermal decomposition of Ca(OCOOCH₃)₂ in the absence of H₂O mainly leads to the reformation of Ca(OCH₃)₂, but this is accompanied by a significant parallel reaction that releases dimethylether (CH₃OCH₃) and CO₂. CaCO₃ is the final product in both decomposition pathways. For CH₃OH/H₂O mixtures containing more than 50 mol % H₂O, direct formation of calcite from Ca(OH)₂ becomes the dominant pathway, although the formation of some Ca(OCOOCH₃)₂ was still evident in the in situ mid-IR spectra of 20 and 40 mol % CH₃OH systems. In the presence of ≤20 mol % H₂O, hydrolysis of the ester led to the formation of an ACC sol–gel. In both the 90 and 100 mol % CH₃OH systems, diffusion-limited ACC → vaterite → calcite transformations were observed. Traces of aragonite were also detected. We believe that this is the first time that these reaction pathways during the carbonation of Ca(OH)₂ in a methanolic phase have been systematically and experimentally characterized.