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Sustainable Use of Electric Arc Furnace Slag as a Fine Aggregate Replacement for Concrete

Sustainable Use of Electric Arc Furnace Slag as a Fine Aggregate Replacement for Concrete

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DOI	10.20900/jsr20250012
刊名	Journal of Sustainability Research JSR
年，卷(期)	2025, 7(1)
作者	Aaron Chadee*,Davatee Maharaj,Yehan Rajapakse,Eleeda Rajack,Shayani Mendis,Hazi Md. Azamathulla,Darshan J. Mehta,Upaka Rathnayake,
作者单位	Department of Civil and Environmental Engineering, The Faculty of Engineering, The University of West Indies, St. Augustine 330110, Trinidad and Tobago ; Department of Civil Engineering, Faculty of Engineering, General Sir John Kotelawala Defence University, Rathmalana 10390, Sri Lanka ; Department of Civil Engineering, Dr. S. & S. S. Ghandhy Government Engineering College, Surat 395001, Gujarat, India ; Department of Civil Engineering and Construction, Faculty of Engineering and Design, Atlantic Technological University, Ash Lane, Sligo F91 YW50, Ireland ;
Abstract	This research provides empirical insights into the mechanical properties of concrete made with fine electric arc furnace slag aggregates. The utilization of fine electric arc furnace slag as aggregates in concrete production could be a catalyst in addressing the current unsustainable extraction rates of the natural non-renewable resources thereby promoting circularity in the economy and achievement of sustainable developmental goals. Using four mix designs with varying percentages of Electric Arc Furnace (EAF) slag (0%, 10%, 15%, and 20%) as fine aggregates; a decrease in the compressive strength values compared to the control mix for concrete mixes containing 10% and 15% EAF slag of fine aggregates, but an increase in the compressive strength at 20% replacement. However, a steady decrease in the tensile strength value for all percentages of EAF slag replacement was noted. It was deduced that, all American Concrete Institute (ACI) 318, Eurocode (EC) 2, and Australian Standard (AS) 3600 standard design codes for normal concrete overestimate the 7-day and 28-day splitting tensile strengths of EAF slag concrete. Moreover, the comparison with related literature shows that EAF slag performs with a unique behaviour compared to other alternative materials which generally hinders both the compressive and tensile strengths of concrete.
KeyWord	concrete; electric arc furnace slag; recycle aggregates; durability; mechanical properties; circularity in the economy
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引用本文

Aaron Chadee*,Davatee Maharaj,Yehan Rajapakse,Eleeda Rajack,Shayani Mendis,Hazi Md. Azamathulla,Darshan J. Mehta,Upaka Rathnayake. Sustainable Use of Electric Arc Furnace Slag as a Fine Aggregate Replacement for Concrete, Journal of Sustainability Research. 2025; 7; (1). https://doi.org/10.20900/jsr20250012.

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