Enhanced Mechanical and Microstructural Properties of Portland Cement Composites Modified with Submicron Metakaolin

Wang, Yao Yu; Li, Jiye; Jiang, Lu; Zhao, Lihua

doi:10.1155/2020/8882385

Cited by 3 publications

(1 citation statement)

References 39 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…9). Moreover, the alkali-active process of MK induced by the destruction-coagulationcondensation-crystallization mechanism occurs promptly at different pH values (Chao et al, 2010;Glukhovsky et al, 1980;Wang et al, 2003). An additional silicon or excellent condition is provided for the generation of C-S-H nuclei (Michel et al, 2011) to accelerate the hydration rate of Portland cement and promote the hardening of pastes.…”

Section: Hydration Heat Evolutionmentioning

confidence: 99%

Recycling utilization of phosphogypsum in eco excess-sulphate cement: Synergistic effects of metakaolin and slag additives on hydration, strength and microstructure

Wang

Shui

Sun

et al. 2022

Journal of Cleaner Production

View full text Add to dashboard Cite

Section: Hydration Heat Evolutionmentioning

confidence: 99%

Recycling utilization of phosphogypsum in eco excess-sulphate cement: Synergistic effects of metakaolin and slag additives on hydration, strength and microstructure

Wang

Shui

Sun

et al. 2022

Journal of Cleaner Production

View full text Add to dashboard Cite

Strength damage mechanism and pore structure evolution of modified Pisha sandstone cement soil with metakaolin

Geng

Jaturapitakkul

Qin

et al. 2022

QJEGH

View full text Add to dashboard Cite

To fully understand the solidification effect of metakaolin (MK) on Pisha-sandstone cement soil, unconfined compressive strength (UCS), ultradepth three-dimensional microscopy (U3DM), nuclear magnetic resonance (NMR), X-ray diffraction (XRD), and scanning electron microscopy (SEM) tests were carried out on the solidified soil. The solidification mechanism of MK was comprehensively analyzed from the perspectives of macromechanics, mesostructure, and micromechanisms. From the perspective of macromechanics, the damage variable V tended to decrease with the increase in MK content, which indicates that the addition of MK helps improve the ability of the solidified soil to resist damage. From a mesoscopic perspective, the addition of MK reduced the average height difference of the surface of the solidified soil. The complexity of the size, number, distribution, and shape of pores in the solidified soil was comprehensively analyzed based on NMR experiments. With the increase in MK content, the proportion of pores with a pore radius > 1 µm decreased, while the fractal dimensions DT and D2 increased. XRD and SEM experiments show that the hydration products (calcium aluminate hydrate and calcium silicate hydrate) formed after the incorporation of MK were tightly combined with the soil particles and filled the pores. A gray entropy correlation analysis carried out to analyze the correlation effect of different pore structures on the strength of the solidified soil showed that the pore sizes of 0–0.1 µm had a large influence on the UCS. This is a valuable finding on the link between the microstructure and macromechanics of solidified soils.

show abstract

The Effect of Tungsten Carbide Nanopowder Agglomerates on the Properties of Cement Materials

Chayka

2021

Bulletin of Belgorod State Technological University Named After. V. G. Shukhov

View full text Add to dashboard Cite

The object of the research is cement samples modified by agglomerates of tungsten carbide nanopowders obtained from carbide waste. The paper considers the influence of tungsten carbide nanopowder on the change in the main cement characteristics (density, water demand, setting time, kinetics of strength gain, compressive strength, bending strength). The optimum additive content in cement materials is 3%. This parameter is estimated by the maximum growth of compressive and flexural strength at all stages of hardening. The effect of WC powder additive on the structure of the cement matrix has been shown. Due to the high dispersibility of WC nanopowder, its particles act as additional crystallization centers, fill in the micropores of the cement stone and create a denser and stronger structure. The results of studying the microstructure of the cement stone with additions of WC powder indirectly confirm the results of strength characteristics. The cement-sand samples with the modifier are found to have a denser crystallized cement-sand stone compared to the control sample (without WC powder addition). The conducted researches have shown perspectivity of application of WC nanoparticles agglomerates as modifying additives for cement materials, which can be used in production of special purpose concrete (hydraulic, radioprotective, etc.). The economic effect of the use of WC nanoadditives obtained from hard-alloy production wastes can be obtained due to a reduction in costs at the stages of construction and operation of structures, buildings, structures based on it.

show abstract

Enhanced Mechanical and Microstructural Properties of Portland Cement Composites Modified with Submicron Metakaolin

Cited by 3 publications

References 39 publications

Recycling utilization of phosphogypsum in eco excess-sulphate cement: Synergistic effects of metakaolin and slag additives on hydration, strength and microstructure

Recycling utilization of phosphogypsum in eco excess-sulphate cement: Synergistic effects of metakaolin and slag additives on hydration, strength and microstructure

Strength damage mechanism and pore structure evolution of modified Pisha sandstone cement soil with metakaolin

The Effect of Tungsten Carbide Nanopowder Agglomerates on the Properties of Cement Materials

Contact Info

Product

Resources

About