Effects of sodium oxide content on the durability of alkali-activated mortar utilizing botswana copper mine tailings and fly ash

This investigation aims to provide experimental data on the performance of alkali-activated mortar made of copper mine tailings (CMT) and fly ash (FA) exposed to acid-sulphate attacks and elevated temperature environments as a measure of durability. FA was used as a replacement material, substitutin...

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Bibliographic Details
Published in:MATEC web of conferences 2022, Vol.364, p.2010
Main Authors: Sannoh, Abraham V. J., Malumbela, Goitseone, Gilayeneh, Victor S.
Format: Article
Language:English
Subjects:
acid and sulphate resistances
Acids
alkali activation
Compressive strength
Copper
copper mine tailings
Durability
elevated temperature
Exposure
Fly ash
High temperature
Magnesium
Mortars (material)
Sodium
Sodium hydroxide
Sodium sulfate
Sulfates
Tailings
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Summary:This investigation aims to provide experimental data on the performance of alkali-activated mortar made of copper mine tailings (CMT) and fly ash (FA) exposed to acid-sulphate attacks and elevated temperature environments as a measure of durability. FA was used as a replacement material, substituting 20 to 40% of the CMT by mass, and sodium hydroxide was the alkaline activator, which was added in terms of Na 2 O content by mass of the total binder at 5%, 10%, and 15%. The durability performance of alkali-activated mortar was evaluated against 5 % and 10% concentrations of sulphuric and hydrochloric acids, and magnesium and sodium sulphates up to 180 days of exposure, as well as elevated temperature environment. The specimens were first visually examined, and weight change was measured before being exposed to an elevated temperature environment and the residual compressive strength was measured. It was observed that Na 2 O content and elevated temperature environment influence the residual compressive strength of alkali-activated mortar. Increasing the Na 2 O content for all CMT-FA-based mortar samples performed well in sulphates and acids mediums in terms of durability, but with a slight reduction in its durability performance in terms of residual compressive strength. However, these effects were more profound in samples exposed to acids, particularly those with lower FA replacement levels and sodium oxide content. For the high-temperature exposure, the residual compressive strength of all CMT-FA samples was much higher than the initial values. The findings also revealed that the partial replacement of CMT by FA significantly improved the residual compressive strength in terms of the durability performance of the alkali-activated mortar
ISSN:2261-236X
2274-7214
2261-236X
DOI:10.1051/matecconf/202236402010