Ebenezer O. Fanijo scite author profile

The type of steel furnace slag (SFS), including electric arc furnace (EAF) slag, basic oxygen furnace (BOF) slag, ladle metallurgy furnace (LMF) slag, and argon oxygen decarburization (AOD) slag, can significantly affect the composite properties when used as an aggregate or as a supplementary cementitious material in bound applications, such as concretes, mortars, alkali-activated materials, and stabilized soils. This review seeks to collate the findings from the literature to express the variability in material properties and to attempt to explain the source(s) of the variability. It was found that SFS composition and properties can be highly variable, including different compositions on the exterior and interior of a given SFS particle, which can affect bonding conditions and be one source of variability on composite properties. A suite of tests is proposed to better assess a given SFS stock for potential use in bound applications; at a minimum, the SFS should be evaluated for free CaO content, expansion potential, mineralogical composition, cementitious composite mechanical properties, and chemical composition with secondary tests, including cementitious composite durability properties, microstructural characterization, and free MgO content.

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Stabilization of a Clayey Soil with Ladle Metallurgy Furnace Slag Fines

Brand

Singhvi

Fanijo

et al. 2020

Materials

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The research study described in this paper investigated the potential to use steel furnace slag (SFS) as a stabilizing additive for clayey soils. Even though SFS has limited applications in civil engineering infrastructure due to the formation of deleterious expansion in the presence of water, the free CaO and free MgO contents allow for the SFS to be a potentially suitable candidate for clayey soil stabilization and improvement. In this investigation, a kaolinite clay was stabilized with 10% and 15% ladle metallurgy furnace (LMF) slag fines by weight. This experimental study also included testing of the SFS mixtures with the activator calcium chloride (CaCl2), which was hypothesized to accelerate the hydration of the dicalcium silicate phase in the SFS, but the results show that the addition of CaCl2 was not found to be effective. Relative to the unmodified clay, the unconfined compressive strength increased by 67% and 91% when 10% and 15% LMF slag were utilized, respectively. Likewise, the dynamic modulus increased by 212% and 221% by adding 10% and 15% LMF slag, respectively. Specifically, the LMF slag fines are posited to primarily contribute to a mechanical rather than chemical stabilization mechanism. Overall, these findings suggest the effective utilization of SFS as a soil stabilization admixture to overcome problems associated with dispersive soils, but further research is required.

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Quantitative measurement of corrosion at the nanoscale by in situ spectral modulation interferometry

Fanijo

Thomas

Zhu

et al. 2022

Materials Characterization

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Alkali-silica reaction (ASR) in concrete structures: Mechanisms, effects and evaluation test methods adopted in the United States

Fanijo

Kolawole

Almakrab

2021

Case Studies in Construction Materials

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State-of-the-art review on the use of sugarcane bagasse ash in cementitious materials

Kolawole

Babafemi

Fanijo

et al. 2021

Cement and Concrete Composites

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Performance of laterized concrete made with palm kernel shell as replacement for coarse aggregate

Fanijo

Babafemi

Arowojolu

2020

Construction and Building Materials

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ASR mitigation using binary and ternary blends with waste glass powder

Fanijo

Kassem

Ibrahim

2021

Construction and Building Materials

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Blended cement binders containing bamboo leaf ash and ground clay brick waste for sustainable concrete

et al. 2021

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