Investigation of type, size, and dosage effects of superabsorbent polymers on the hydration development of high-performance cementitious materials.

The low water-to-binder ratio commonly used for high-performance cementitious materials is known to limit the degree of hydration of their cement particles. This issue often cannot be resolved with conventional external curing methods, primarily because of the low permeability of such materials. Thus, internal curing methods are devised to improve the degree of hydration and maximize the use of cement particles. Focusing on superabsorbent polymers (SAPs) as one of the main internal curing agents, this study investigates the effects of various types, sizes, and dosages of SAPs on the hydration kinetics of high-performance cementitious mixtures. For this purpose, the main performance characteristics of SAPs were characterized first. Paired with monitoring the temperature development patterns in a set of SAP-contained mixtures, thermogravimetric analyses (TGA) and X-ray diffractometry (XRD) investigations were systematically performed to measure the phase consumption of cement particles. Scanning electron microscope (SEM) image analyses were then employed to assess the materials deposited in the remaining SAP voids. By providing original insights into the hydration development process, this study's outcome guides the use of SAPs with the ultimate goal of maximizing the hydration degree of cement particles, paving the way to minimizing the carbon footprint of high-performance cementitious materials. • Superabsorbent polymers (SAPs) were investigated for various early-age characteristics. • Effects of types, sizes, and dosages of SAPs on hydration kinetics were studied. • Temperature development and cement consumption patterns were recorded and compared. • The materials deposited in the remaining SAP voids were systematically evaluated. • Correlations were established between direct and indirect investigation approaches. [ABSTRACT FROM AUTHOR]