Enhanced carbonation reactivity of wollastonite by rapid cooling process: Towards an ultra-low calcium CO2 sequestration binder

To enhance the carbonation reactivity of wollastonite (CS), three different calcination processes were adopted to synthesis CS with different crystal structures. The effects of the cooling process on the polymorphs, carbonation reactivity, and CO2 sequestration capacity of CS were measured and evaluated, and its carbonation hardening properties and microstructure evolution were also explored. The results indicated that the carbonation reactivity of CS was enhanced by the rapid cooling process due to the inhibition of the polymorphic transition of alpha-CS to beta-CS. The enhanced carbonation reactivity was attributed to the distorted CaOx polyhedra and extended Ca-O distance in alpha-CS, which made the dissolution of alpha-CS to leach Ca2+ easier. The CO2 sequestration capacity and compressive strength of highly reactive CS reached 27.2% and 92.3 MPa, respectively, after carbonation for 24 h. Therefore, it was demonstrated that highly reactive CS can be adopted as ultra-low calcium and CO2 sequestration binder.

Automated summary

The study demonstrates that rapid cooling process can enhance the carbonation reactivity of wollastonite, leading to better CO2 sequestration capacity and compressive strength. This research provides new insights for the application of highly reactive CS.