Abstract
Concrete is a major construction material that produces high levels of carbon dioxide in its manufacturing process. Hence the construction sector is responsible for relevant environmental impacts. This justifies the need to find materials as green and ecological alternatives to common Portland cement. Geopolymers represent the most promising alternative due to its proven durability, mechanical and thermal properties. This study investigates the effects of solid-to-liquid and alkali activator ratios on the synthesis of slag-based pure geopolymer and their relation to the geopolymerization process. Two activating solutions were used: a) a mixture of sodium hydroxide, sodium silicate, and water; and b) a mixture of potassium hydroxide solution, potassium silicate, and water. As precursor material, ground blast furnace slag was used. Precursors and activators were mixed with solid-to-liquid ratios in range of 1.5 to 2.2. In the first stage of the study, the mechanical properties were evaluated for each activating solution. In the following stage, different formulations, with variations in the water percentage and solid-to-liquid ratio were tested for mechanical properties and SEM observations. Test results indicate that the resulting geopolymer has the potential for high compressive strength and is directly affected by the composition of the activating solution. It can also be observed that compressive strength was affected by solid-to-liquid ratio and % of water added to the mixture, and strength increased with ageing day.
Highlights
In construction, concrete is one of the most widely used substances in the world and requires large amounts of Portland cement, which produces large amounts of carbon dioxide (CO2)
The experimental studies performed aimed to study the effect of activating solution and different formulations on the geopolymerization process for Ground blast furnace slag (GBFS) alkali-activated geopolymers
Analyzing the results for the effect of activation solution type, it was concluded that the solution that presented the best geopolymerization process was Na-Si
Summary
Concrete is one of the most widely used substances in the world and requires large amounts of Portland cement, which produces large amounts of carbon dioxide (CO2) With this very significant detriment to the environment, comes the importance of innovative and alternative ways of substituting this material [1]. Based on the composition used, it is able to acquire other properties such as higher initial resistance [5], chemical resistance and refractoriness [6] They behave to organic polymers, i.e. the ability to stabilize at low temperatures and in a short time, geopolymers are harder, inorganic, stable and non-flammable at temperatures up to 1250 °C [7]
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