Litcius/Paper detail

Substitutive effect of nano-SiO2 for silica fume in ultra-high-performance concrete on fiber pull-out behavior

Taekgeun Oh, Booki Chun, Seung Kyun Lee, Wonkyo Lee, Nemkumar Banthia, Doo‐Yeol Yoo

2022Journal of Materials Research and Technology42 citationsDOIOpen Access PDF

Abstract

This study investigated the effect of substituting nano-SiO2 for silica fume on the fiber-matrix interfacial bond performance of ultra-high-performance concrete (UHPC). In this study, silica fume was substituted by nano-SiO2 in the weight range of 0–50%. The degree of pozzolanic reaction of binder materials was evaluated using the thermogravimetric analysis (TGA) and compressive strength measurement. The single fiber pull-out test was conducted along with a measurement of autogenous shrinkage to evaluate the interfacial bond. The degree of pozzolanic reaction of nano-SiO2 was found to be higher than that of other binder materials. Although the packing density was predicted to increase continuously up to a substitution ratio of 50%, the highest compressive strength was obtained when 10% of silica fume was replaced by nano-SiO2, which improved the compressive strength by 5.9% compared to that of the plain sample. The autogenous shrinkage increased with an increasing content of nano-SiO2 up to 30%; however, it remained similar beyond the nano-SiO2 content of 30%. The best pull-out performance was obtained when 20% of silica fume was replaced by nano-SiO2, in which the average bond strength and pull-out energy were improved by approximately 21 and 68%, respectively. Therefore, substitution of 10–20% of silica fume by nano-SiO2 was recommended as an optimal amount considering the improvements of the compressive strength and fiber-matrix bond performance of UHPC.

Topics & Concepts

Silica fumeMaterials scienceCompressive strengthPozzolanComposite materialShrinkageNano-Bond strengthPozzolanic activityFiberThermogravimetric analysisPozzolanic reactionCementChemical engineeringPortland cementAdhesiveLayer (electronics)EngineeringConcrete and Cement Materials ResearchInnovative concrete reinforcement materialsAdvanced ceramic materials synthesis