Abstract
Electric arc furnace slag (EAF) and sandstone waste (SW) are two of the most abundantly generated industrial wastes whose utilization as precursors and supplementary cementitious materials has not been exhaustively studied. The current research study comprehensively investigates the effects of incorporating varying proportions (0–90%) of re-melted EAF as a co-additive on the engineering properties of elevated (80 °C) and ambient (30 °C) cured alkali-activated SW-based binders. Extensive laboratory tests were conducted to assess the physio-mechanical and durability performance of the resulting alkali-activated materials (AAM). Detailed mineralogical and microstructural characterization of SW, EAF, and alkali-activated samples was carried out using sophisticated analytical techniques. Results advocated that irrespective of the curing temperatures, SW-based AAM showed improved setting behavior, compressive strength, water absorption, and porosity characteristics with the increment of EAF at all substitution levels due to the concomitant development of CASH-CSH-NASH gel phases. Overall, it can be inferred that EAFs as a pozzolanic material successfully augmented the properties of SW-based alkali-activated binders, providing an efficient solution for disposal and negative environmental impacts associated with industrial wastes.
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AS is involved in conceptualization, methodology, formal analysis and investigation, data curation, validation, visualization, writing—original draft preparation. DB is involved in project administration, supervision, resources, writing, review, and editing. SC is involved in conceptualization, supervision, writing, review, and editing.
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Samadhiya, A., Bhunia, D. & Chakraborty, S. Alkali-Activation Potential of Sandstone Wastes with Electric Arc Furnace Slag as Co-additive. Arab J Sci Eng 49, 5817–5833 (2024). https://doi.org/10.1007/s13369-023-08514-0
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DOI: https://doi.org/10.1007/s13369-023-08514-0