One-part alkali-activated materials (AAMs) are developed to improve conventional two-part systems. One-part AAMs technology has been used in cement binders to produce concrete, mortar, and paste. Current research mainly focuses on synthesizing raw materials obtained from industrial and agricultural waste as the main aluminosilicate precursors of the cement binder for a concrete application. The one-part AAMs were reported to have higher early compressive strength at 7 days of age, contributed by its fast-setting time, mainly when the binder activates by a higher dosage of alkaline activator and containing OPC-rich. Due to bonding issues, single or combination, FA/GGBFS/MK precursors were reported as unsuitable for use as a concrete repair material. They were the reason for the lack of one-part AAMs application of mortar compared to concrete usage. This study was conducted to determine the potential of one-part AAMs used as concrete patch mortar by investigating its rheology and mechanical properties. The compressive strength of the mortar was tested under lab ambient temperature in the tropical climate country of Malaysia. The setting time of fresh mortar and bonding strength were set under controlled lab temperature. The one-part alkali-activated mortar was composed of hybrid aluminosilicate precursors between fly ash (FA), Ground Granulated Blast Furnace Slag (GGBFS) and ordinary Portland cement (OPC). A low alkaline activator of solid potassium carbonate was used for the geopolymerization process. Three types of solid admixtures were added to complete the composition of the new mix design. The experiment's outcome showed that the mortar composed with the combination of conventional Portland cement and industrial waste products has compressive and pull-off adherence strength that meets with Class R3—EN1504-3 standard for structural concrete repair materials requirement.
Alkali-activated materials (AAMs) have been widely used as an alternative to Portland cement. This production of AAMs emits lesser carbon dioxide by utilizing industrial waste products to make this cement binder technology greener and more sustainable. The conventional two-part system comprises solid aluminosilicate precursors with an alkali solution to activate the AAMs. However, higher alkalinity of the liquid activator is required to complete the geopolymerazation process, making the cementitious materials costly and sticky, and thus not convenient to handle on the construction site, affecting the worker’s safety. A one-part AAMs system was introduced to overcome the two-part system’s shortcomings. The alkali solution is now replaced with a solid alkali activator which is easier and more practical to apply at construction sites. This study was carried out to evaluate the mechanical performance of one-part alkali AAMs in the form of mortar by conducting compressive and flexural strength, modulus of elasticity, and tensile strength tests at 28 days of curing age under laboratory experiments in the tropical climate of Malaysia. A drying shrinkage test was also performed to detect its durability. Three types of solid admixtures were added to complete the composition of the novel mix design formulation. According to the results obtained, the mechanical strength of one-part alkali-activated mortar achieved the minimum requirement for Class R3 structural concrete repair materials as per EN1504-3 specifications. This eco-friendly cement binder has excellent potential for further engineering development, particularly to become a new concrete repair product in the future.
One-part alkali-activated materials (AAMs) are an alternative material to respond to the shortcoming of the conventional two-part systems. One-part AAMs are more practical and safer to handle from transporting to the casting stage on site. It can be applied in the form of paste, mortar, and concrete, providing more options than an ordinary cement binder. The most common aluminosilicate precursors sources for the one-part AAMs are the combination or single raw material of fly ash, ground granulated blast furnace slag and metakaolin. However, it was found that the one-part AAMs experienced high porosity levels primarily due to their inconsistent pore structures that affect their long-term performance. One-part AAMs mortar is one of the cementitious products used as concrete repair materials that may be affected by these weaknesses. Nevertheless, the combination of aluminosilicate precursor by-products with the ordinary Portland cement or hybrid AAMs help to develop a robust performance mainly used as a patching product for concrete repair materials. This hybrid one-part AAMs mortar can be composed with other admixtures with a suitable mix design to ensure its stability and useable in the form of a fresh and hardened state. Unlike the ordinary concrete, hybrid one-part AAMs have significantly strengthened growth beyond the 28th day. In this study, the mechanical strength of the mortar increased over time up to 63 N/mm2 at 56 days of curing age, shorter setting time and workable comparable to the control samples. In addition, the water to binder ratio of 3.0 activated the dry mixes and significantly improved the physical and microstructure of the hybrid one-part AAMs mortar.
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