Effects of controlled release silica nanocapsules containing sucrose on the heat release of cement hydration.

The usage of chemical admixtures, such as starch-based materials, is a common approach to addressing the thermal cracking problem of cementitious materials. Capsule-based controlled release technique enables the adjustable action time of loaded chemical admixture and thus reveals the potential on inhibiting the exothermic process of cement hydration. Three types of silica-based nanocapsules loaded with 53–63% sucrose retarder are firstly prepared by interfacial polymerization in water-in-oil (W/O) emulsion. The release characteristics of three types of nanocapsules are precisely tuned by varied preparation conditions. The effects of nanocapsules on the exothermic process of cement hydration have been investigated through calorimetry measurements. All prepared nanocapsules not only delay the appearance of the main hydration peak as the retardation effect but also reduce the maximum heat flow of the main hydration peak, to some extent, as the depression effect. The depression and retardation effects are improved with the increased dosage and slower release rate of added nanocapsules. The relationship between the two effects and the action time of loaded sucrose suggests the importance of persistently inhibiting the cement hydration over the entire accelerating and decelerating processes, which can be estimated by the time window between the action of sucrose (50% release time) and occurrence of main hydration peak. [Display omitted] • A series of controlled-release silica nanocapsules containing sucrose were successfully prepared and characterized. • The nanocapsules of diverse release behaviors affect the appearance time and maximum heat flow of the main hydration peak. • The depression and retardingretardation effects dependent on the release characteristics of nanocapsules are deeply investigated. • The inhibiting mechanism is proposed as sucrose's continuous release and adsorption onto early precipitated C-S-H. [ABSTRACT FROM AUTHOR]