The microstructure of inorganic polymers (IP) formed from fayalite slag was investigated as a function of the composition of different activating solutions. The starting slag was 80 wt% amorphous, and after activation using sodium silicate solutions with varying SiO2/Na2O molar ratios, the amorphous phase dissolved and a binder phase was formed. The morphology of this binder, including the population and size of remnant particles and pores, was dependent on the particular activating solution used, and became denser as the level of silicate rose. 57Fe Mössbauer spectroscopy revealed that the IP synthesis reaction is combined with the oxidation of Fe2+ from the fayalite slag to Fe3+ in the inorganic polymer binder. The reaction extent varied and could be quantified using the absorption areas of these ions. Data corroborate that the Fe2+ ions in the amorphous part of the fayalite slag and the Fe3+ ions in the new binder phase had an average oxygen‐coordination number of 5.
Three types of binders were investigated by combining a water granulated fayalite slag and three different activating solutions (NaOH, SH; Na-silicate, SS; and a 1:1 mixture of the two, SH + SS). A reactivity test proved that the slag dissolves in the alkaline environment, releasing both Si and Al. Through rheological measurements it was found that the most alkaline solution (SH) led to a very fast structure build-up, followed by the activating solution SS+SH; when SS was used, the storage modulus did not increase even after 2 h. A similar trend was observed by calorimetry, where the paste with SH resulted in heat release within minutes, followed by SH + SS. These transformations were also followed by in situ ATR-FTIR, indicating changes in the vibrational bands attributed to asymmetric stretching vibration of [SiO 4 ] with 3 or 4 NBO/Si. In the case of the sample activated with SH, a new band appeared after 96 h and continued to increase in intensity at later times. For SS + SH activating solution, a new band appeared after 96 h, increasing over time, whereas the originally present band at 940 cm -1 became more distinct. For the sample with only SS, no vibrational changes were detected after 24 h. In conclusion, the fayalite slag is a reactive material that can undergo microstructural changes toward new reaction products, with the choice of the activating solution being a crucial factor in the process.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.