Influence of ground granulated blast furnace slag on the early hydration and microstructure of alkali-activated converter steel slag binder

Alkali-activated materials are low-environmental-impact binders that can be obtained from the alkaline activation of industrial wastes. In this study, converter steel slag as the major raw material and ground granulated blast furnace slag (GBFS) as the modified material were activated by water glass with a modulus of 1.5 and a Na2O dosage of 4%. The hydration process, microstructure and compressive strength of alkali-activated composite materials were investigated. The results show that adding GBFS accelerates the initial dissolution of the particles, leading to higher first exothermic peaks. But adding GBFS decelerates the formation of hydration products, resulting in the delay of the second exothermic peaks. Adding GBFS has no significant effect on the cumulative hydration heat, Ca(OH)(2)content and the type of gel in the alkali-activated steel slag systems. However, with increasing GBFS content, the Ca-Si ratio in the gel decreases, and the Al-Si ratio increases. Adding GBFS can refine the pore structure and produces more Si-O-Si bonds in gels, resulting in a significant increase in the compressive strength. The improvement effect of GBFS on the compressive strength is more obvious at a later stage than at an earlier stage.

Automated summary

Alkali-activated materials are environmentally friendly binders synthesized from industrial wastes. This study investigated the hydration process, microstructure, and compressive strength of alkali-activated composite materials using converter steel slag and ground granulated blast furnace slag. The addition of GBFS affected the hydration process by accelerating initial dissolution and delaying the formation of hydration products.