An approach to improve the reactivity of basic oxygen furnace slag: Accelerated carbonation and the combined use of metakaolin.

• Carbonation of steel slag results in the formation of CaCO 3 barrier which blocks the reaction of silica gel. • The incorporation of metakaolin enhances the reactivity of steel slag by promoting the reaction of CaCO 3 and formed silica gel. • The coupled substitution of carbonated steel slag and metakaolin leads to significant improvement of strength and water absorption. This study aims to promote the reactivity of basic oxygen furnace slag (BOFS) through accelerated carbonation and the combined use of metakaolin (MK). Influences of the incorporation of the combination of carbonated BOFS and MK at various cement substitution levels on strength development, water absorption, phase composition, and microstructure are investigated. It is revealed that the coupled substitution with carbonated BOFS and MK improved the formation of carboaluminate phases and stabilized ettringite owing to the synergic reaction between metakaolin and CaCO 3 derived from the carbonation of BOFS; and the consumption of CaCO 3 facilitates the pozzolanic reaction of the amorphous SiO 2 gel formed during carbonation, generating more hydration products. All these reactions contribute to improved impermeability and enhanced strength development; 45% of ordinary Portland cement (OPC) can be replaced while achieving a comparable strength to sample consisting of 100% OPC. In addition, compared to the sample incorporated with uncarbonated BOFS and MK, the compressive strength of the sample blended with 30% carbonated BOFS and 15% MK was improved by 32.5% at the age of 56d; meanwhile, the water absorption during 72 h was lowered by 67.7%. In terms of the environmental impact, the CO 2 emission and intensity for sample incorporated with 30% carbonated BOFS and 15% MK only account for 59% and 62% of those in sample comprised of 100% OPC. The study proposes an approach to improve the reactivity of BOFS efficiently and sequestrate a significant amount of CO 2 simultaneously. [ABSTRACT FROM AUTHOR]