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On the chemo-mechanical evolution process of high-volume slag cement paste

Minfei Liang, Yu Zhang, Shan He, Yu Chen, Erik Schlangen, Branko Šavija

2023Construction and Building Materials18 citationsDOIOpen Access PDF

Abstract

This study investigated the evolution process of high-volume slag cement (HVSC) paste from a chemo-mechanical standpoint. HVSC specimens with a 70 w.t. % slag replacement rate were studied at various ages. Evolution of phase assemblage, microstructure development, and micromechanical properties were analyzed using TGA/XRD/MIP/SEM-EDS and nano-/micro-indentation techniques. A two-scale micromechanical model was built to predict the effective elastic modulus based on the nanoindentation results. Key findings include: 1) Between 7 and 28 days, the formation of calcium silicate hydrate (C-S-H) gel phase improves the effective elastic modulus by filling capillary pores; 2) From 28 to 90 days, the phase assemblage and microstructure remain stable, with a transition from low-density to high-density C-S-H; 3) Between 90 days and 2 years, slag rims produced by slag grains result in increased elastic modulus; 4) The two-scale micromechanical model, combined with nanoindentation data, accurately predicts the effective modulus of HVSC composites, although the unhydrated slag grains-hydrated cement matrix interface may cause an overestimation at an early age. With longer curing time, this interface disappears owing to the continuous hydration of large slag particles and therefore a good match is found between the modelling and experimental results.

Topics & Concepts

Materials scienceMicrostructureNanoindentationComposite materialCalcium silicate hydrateElastic modulusSlag (welding)Ground granulated blast-furnace slagCementModulusPhase (matter)Organic chemistryChemistryConcrete and Cement Materials ResearchMagnesium Oxide Properties and ApplicationsInnovative concrete reinforcement materials