Litcius/Paper detail

Physicochemical effects of nanosilica on C <sub>3</sub> A/C <sub>3</sub> S hydration

Pengkun Hou, Xinming Wang, Piqi Zhao, Kejin Wang, Shiho Kawashima, Qinfei Li, Ning Xie, Xin Cheng, Surendra P. Shah

2020Journal of the American Ceramic Society40 citationsDOI

Abstract

Abstract In this paper, C 3 A‐gypsum and C 3 A‐C 3 S‐gypsum model cement systems with and without nanosilica were studied. The effects of nanosilica on the early stage cement hydration, particularly C 3 A hydration, were assessed through the heat of hydration (isothermal calorimetry), phase assemblage (quantitative X‐ray diffraction), zeta potential, ion concentration measurements, and morphology (scanning electron microscopy) examinations. The results indicate that while promoting C 3 S hydration, nanosilica retarded C 3 A hydration in both the systems studied. The retardation was caused by the adsorption and coverage of nanosilica on C 3 A surfaces through the electrostatic interaction, thus decreasing the C 3 A dissolution rate and hindering the precipitation of hydration products. Consequently, the reduced gypsum consumption rate and the seeding effect of nanosilica further promoted C 3 S hydration. These findings suggest that nanosilica and other silica‐based nanoparticles can physicochemically influence hydration of cement‐based materials, and a better understanding of these influencing mechanisms can help optimize performances of nanoparticle‐modified cement‐based materials.

Topics & Concepts

CementDissolutionChemical engineeringMaterials scienceZeta potentialNanoparticleGypsumScanning electron microscopeIsothermal processPrecipitationHydration reactionComposite materialNanotechnologyThermodynamicsEngineeringPhysicsMeteorologyConcrete and Cement Materials ResearchInnovative concrete reinforcement materialsMagnesium Oxide Properties and Applications