Evaluating the performance of high volume fly ash-blended-cement mortar individually containing nano- and ultrafine micro-magnesia

This work focuses on the individual impact of nano- and ultrafine micro magnesia (N–MgO and UM-MgO, respectively) on the early performance of high volume fly ash (FA)-blended-cement mortar (CM). N–MgO and UM-MgO were synthesized using a thermal treatment of lightweight hydromagnesite at 550 and 1100...

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Bibliographic Details
Published inJournal of Building Engineering Vol. 36; p. 102129
Main Authors Abdel-Gawwad, Hamdy A., Metwally, Khaled A., Tawfik, Taher A., Mohammed, Mona S., Hassan, Hassan Sultan, Heikal, Mohamed, El-Kattan, Ibrahim M.
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.04.2021
Subjects
Compressive strength
Early-hydration
Environmental pollution
Fly ash
Nano-magnesium oxide
Fly ash
Compressive strength
Environmental pollution
Nano-magnesium oxide
Early-hydration
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Summary:This work focuses on the individual impact of nano- and ultrafine micro magnesia (N–MgO and UM-MgO, respectively) on the early performance of high volume fly ash (FA)-blended-cement mortar (CM). N–MgO and UM-MgO were synthesized using a thermal treatment of lightweight hydromagnesite at 550 and 1100 °C, respectively. Different contents of MgOs (1, 3, and 5 wt% by weight of powder) were individually added to FA-blended-CM. The results revealed that the N–MgO exhibits higher efficiency in the acceleration of early PC-FA system hydration compared to UM-MgO at all addition levels. The addition of 1, 3, and 5 wt% N–MgO to FA-blended-CM has resulted in the enhancement of 3-days compressive strength value by ~26, 94, and 103%, respectively; whereas the UM-MgO shows a modest effect. The small particle size, low crystallinity, and high hydration reactivity are the dominant features of N–MgO, which reflect on the enhancement of FA-pozzolanic activity accompanied by the acceleration of strength-giving-phases formation at early ages of hydration. To achieve the sustainability, we have recommend the use of N–MgO, as it contributes to cost minimization, energy saving, and the mitigation of carbon footprint. •Nano- and micro-MgO were used to enhance the performance of fly ash cement mortar.•Nano-MgO exhibited higher hydration reactivity compared with ultrafine micro-MgO.•Cement mortar containing 5 wt% nano-MgO exhibited the highest early performance.•The properties of cement mortar depend on the particle size and reactivity of MgO.•MgO interacts with amorphous aluminosilicate, yielding magnesium silicate hydrate.
ISSN:2352-7102
2352-7102
DOI:10.1016/j.jobe.2020.102129