01157588

Component

https://doi.org/10.3141/2141-03

http://scholar.google.com...azua&publication_year=2010

The effect of 5- to 70-nm SiO2 nanoparticles on the mechanical properties of nanocement materials was examined. The strength development of portland cement with nano-SiO2 and superplasticizing admixture was investigated. Experimental results demonstrate an increase in the compressive and flexural strengths of mortars with SiO2 nanoparticles. Because the distribution of nano-SiO2 particles within the cement paste plays an essential role and governs the overall performance of these products, the addition of a superplasticizer was proposed to facilitate the distribution of nano-SiO2 particles. The application of superplasticizer and high-speed dispergation were found to be effective disagglomeration techniques to improve the strength of superplasticized portland cement mortars, which reached up to 63.9 and 95.9 MPa (Sample 4B3, synthesized by using the sol–gel method in a base reaction medium at ethanol-to-tetraethoxysilane and water-to-tetraethoxysilane molar ratios of 24) at the ages of 1 day and 28 days, respectively. At corresponding ages, the compressive strength of reference portland cement mortars was 53.3 and 86.1 MPa. It is concluded that the effective dispersion of nanoparticles is essential to obtain composite materials with improved performance.

01157583

NANO10-0054

English

pp 10-14

2010

Transportation Research Record: Journal of the Transportation Research Board

9780309142762

Print

Figures (2) ; References (22) ; Tables (2)

Cement mortars; Compressive strength; Dispersions (Chemistry); Flexural strength; Nanostructured materials; Portland cement; Superplasticizers

Nano-silicon dioxide

Materials; I32: Concrete

TRIS, TRB

May 24 2010 3:42PM

• Atomic Force Acoustic Microscopy to Measure Nanoscale Mechanical Properties of Cement Pastes
• Atomic Force Microscopy Examinations of Mortar Made by Using Water-Filled Lightweight Aggregate
• Comparative Study of the Effects of Microsilica and Nanosilica in Concrete
• Homogenization Model Examining the Effect of Nanosilica on Concrete Strength and Stiffness
• Influence of Additions of Anatase TiO2 Nanoparticles on Early-Age Properties of Cement-Based Materials
• Influence of Micro- and Nanoclays on Fresh State of Concrete
• Influence of Nano-SiO2 Addition on Microstructure and Mechanical Properties of Cement Mortars for Ferrocement
• Micro- and Nanoscale Characterization of Effect of Interfacial Transition Zone on Tensile Creep of Ultra-High-Performance Concrete
• Nanoindentation of Alkali-Activated Fly Ash
• Nanostructure and Microstructure of Cement Concrete Incorporating Multicementitious Composites
• Nanotechnology: New Tools to Address Old Problems
• Observation of Cement Paste Microstructure Evolution
• Photocatalytic Properties of Cement-Based Plasters and Paints Containing Mineral Pigments
• Seeding Effect of Nano-CaCO3 on the Hydration of Tricalcium Silicate
• Small Changes Can Make a Great Difference
• The Fresh State: From Macroscale to Microscale to Nanoscale