Abstract
Concrete mixtures consisting of nanomaterials and fly ash have been shown to be effective for improving the performance of concrete. This study investigates the combined effects of nano-CaCO3 and fly ash on the mechanical properties and durability of concrete; the mix proportion is optimized through orthogonal experiments. In the first phase, nine concrete mixtures were prepared with three water-to-binder ratios (0.4, 0.5, and 0.6), three fly ash contents (15%, 20%, and 25% replacement of the cement weight), and three nano-CaCO3 contents (1%, 2%, and 3% replacement of the cement weight). Based on the orthogonal analysis, the optimal concrete mix proportion was determined as a water-to-binder ratio of 0.4, 20% fly ash, and 1% nano-CaCO3. In the second phase, further investigations were carried out to examine the superiority of the optimal concrete and evaluate the synergistic effect of nano-CaCO3 and fly ash. The results showed that nano-CaCO3 contributed to increasing the compressive strength of fly ash concrete at the early ages, but its effect was quite limited at later ages. Furthermore, the scanning electron microscopy analysis revealed that the seeding effect, filling effect, and pozzolanic effect were the primary mechanisms for the improvement of concrete performance.
Highlights
In recent years, concrete has been used extensively for the construction of high-rise buildings and marine structures as well as for long-span bridges under harsh environmental conditions [1]
Sato and Diallo [22] studied the influence of nano-CaCO3 on cement hydration, and the results revealed that the rapid growth of calcium silicate hydrate (C-S-H) was significantly improved by adding nano-CaCO3 owing to the seeding effect of the nanoparticles
Supit and Shaikh [23] evaluated four different contents of nano-CaCO3 added to fly ash concrete, and the results showed that the addition of 1% nano-CaCO3 provided an optimal improvement in the compressive strength of concrete
Summary
Concrete has been used extensively for the construction of high-rise buildings and marine structures as well as for long-span bridges under harsh environmental conditions [1]. To satisfy the demands of these applications, modern concrete materials must possess high strength, toughness, and durability. As a by-product of industrial processes, the addition of fly ash to concrete benefits the environment and confers economic benefits [3]. Fly ash possesses pozzolanic activity that reacts with calcium hydroxide (CH) during cement hydration, forming additional hydration products such as calcium silicate hydrate (C-S-H) and calcium aluminate hydrate (C-A-H) [4]. Most previous studies [5,6,7,8,9,10] have shown that these hydration products of the pozzolanic reaction can effectively improve the density of concrete, leading to higher strength and better durability. The pozzolanic reaction of fly ash is slow, with lower strength at early ages, which remains a concern
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