Abstract
In a climate neutral world, the life cycle greenhouse gas (GHG) emissions of precipitated calcium carbonate (PCC) have to be reduced towards net-zero. Mineral carbonation processes allow to do so by replacing the carbon rich calcium source limestone by carbon free industrial mineral wastes. Various processes have been investigated in literature. They exhibit the benefit of little to no feedstock related emissions and high energy savings due to the avoidance of the CaCO3 calcination step. However, the nature of the process changes significantly, which requires a fundamental understanding of the new mechanisms controlling the process of CO2 absorption and CaCO3 precipitation. Within this work, a CO2 rich gas is contacted with a calcium rich aqueous feed in a continuous reactive crystallizor. The CO2 selectively absorbs and precipitates as either vaterite or calcite. The effect of the liquid and gas feed flow rates, of the feed stoichiometric ratio and of the residence time on key performance indicators, such as the CO2 capture efficiency the CaCO3 precipitation efficiency and the features of the final product, is studied experimentally. As expected, these feed characteristics determine the effective stoichiometric ratio of reactants in the liquid phase, ψ. The particle size increases strongly with ψ; vaterite represents the predominant solid phase at ψ < 1 while otherwise a mix of vaterite and calcite was formed, whereas the latter one accounted for 13%–90% in mass of crystals collected. Moreover, ψ of about one exhibits the highest CO2 capture efficiency exceeding 80%.
Highlights
Today, the production of precipitated calcium carbonate (PCC), for use in products such as cleansing agents, paper or plastics, causes carbon dioxide emissions
The production of precipitated calcium carbonate (PCC), for use in products such as cleansing agents, paper or plastics, causes carbon dioxide emissions. Most of these emissions are inherent to the process, since the raw material limestone, CaCO3, is calcinated at about 1,000°C to decompose it into calcium oxide, CaO, and carbon dioxide, CO2
The reactor is filled with a calcium ion rich solution in which CaCO3 seed crystals are suspended, which is put in contact with a gas stream consisting of carbon dioxide and nitrogen, 25/75 v/v, and with a liquid stream
Summary
The production of precipitated calcium carbonate (PCC), for use in products such as cleansing agents, paper or plastics, causes carbon dioxide emissions. Most of these emissions are inherent to the process, since the raw material limestone, CaCO3, is calcinated at about 1,000°C to decompose it into calcium oxide, CaO, and carbon dioxide, CO2. While CO2 from limestone, about two thirds of the total, together with that resulting from the combustion of the fuel needed for calcination, about one third (Anantharaman et al, 2017), is usually released to the atmosphere, CaO is reacted with water in the lime slaking process to form calcium hydroxide, Ca(OH). A slurry of Ca(OH) in water is carbonated with CO2, in an amount exactly equal to that released during calcination, to form the final product, PCC.
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