Alkaline Activation of Basic Oxygen Furnace Slag Modified Gold Mine Tailings for Building Material

Mashifana, Tebogo; Sebothoma, Jessica; Sithole, Thandiwe

doi:10.1155/2021/9984494

Cited by 16 publications

(8 citation statements)

References 49 publications

(61 reference statements)

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“…Mine tailings are a waste material from the mining industry generated during the separation of valuable minerals from invaluable waste [45]. Recent investigations on one-part AAMs used gold mine tailings (GMT), iron ore mine tailings (IMT), lead-zinc mine tailings (LZMT), and vanadium tailings (VT) as precursors [46][47][48][49][50]. GMTsa waste material from mining goldmainly consist of SiO 2 and Al 2 O 3 , and their mineral phase structure is highly crystalline with peaks including quartz, albite, microcline, and muscovite [51].…”

Section: Mine Tailingsmentioning

confidence: 99%

One part alkali activated materials: A state-of-the-art review

El-Zeadani

Bompa

Elghazouli

2022

Journal of Building Engineering

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Section: Mine Tailingsmentioning

confidence: 99%

One part alkali activated materials: A state-of-the-art review

El-Zeadani

Bompa

Elghazouli

2022

Journal of Building Engineering

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“…Sithole et al [ 112 ] studied the mechanical performance of fly ash modified BOFS-based geopolymer masonry bricks and concluded that to meet the ASTM C34-13 for masonry bricks, the most favorable conditions for the geopolymer synthesis were 10% fly ash, 5M sodium hydroxide, and 80 °C curing temperature. In another study, Mashifana et al [ 111 ] explored the utilization of BOFS and gold mine tailings (GMT) for geopolymer synthesis and found that the 5 days compressive strength of the GMT: BOFS geopolymer cured at 90 °C was 20 MPa and 25.7 MPa for sodium hydroxide and potassium hydroxide alkaline activators, respectively, which satisfied the ASTM 34-17a and SANS 227:2007 for burnt masonry units, mine backfill paste, and lightweight civil works. Lee et al [ 113 ] reported the stabilization of BOFS geopolymer and found that the 28-day compressive strength was 30–40 MPa, and its expansion was less than 0.5% after the ASTM C151 autoclave testing.…”

Section: Resultsmentioning

confidence: 91%

“…Figure 10 shows that the morphology of BOFS is composed of non-spherical glassy irregularly shaped microstructures. The observed rougher and cloudy texture surface is attributed to the presence of CaO [ 111 ].…”

Section: Resultsmentioning

confidence: 99%

Geopolymer: A Systematic Review of Methodologies

et al. 2022

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The geopolymer concept has gained wide international attention during the last two decades and is now seen as a potential alternative to ordinary Portland cement; however, before full implementation in the national and international standards, the geopolymer concept requires clarity on the commonly used definitions and mix design methodologies. The lack of a common definition and methodology has led to inconsistency and confusion across disciplines. This review aims to clarify the most existing geopolymer definitions and the diverse procedures on geopolymer methodologies to attain a good understanding of both the unary and binary geopolymer systems. This review puts into perspective the most crucial facets to facilitate the sustainable development and adoption of geopolymer design standards. A systematic review protocol was developed based on the Preferred Reporting of Items for Systematic Reviews and Meta-Analyses (PRISMA) checklist and applied to the Scopus database to retrieve articles. Geopolymer is a product of a polycondensation reaction that yields a three-dimensional tecto-aluminosilicate matrix. Compared to unary geopolymer systems, binary geopolymer systems contain complex hydrated gel structures and polymerized networks that influence workability, strength, and durability. The optimum utilization of high calcium industrial by-products such as ground granulated blast furnace slag, Class-C fly ash, and phosphogypsum in unary or binary geopolymer systems give C-S-H or C-A-S-H gels with dense polymerized networks that enhance strength gains and setting times. As there is no geopolymer mix design standard, most geopolymer mix designs apply the trial-and-error approach, and a few apply the Taguchi approach, particle packing fraction method, and response surface methodology. The adopted mix designs require the optimization of certain mixture variables whilst keeping constant other nominal material factors. The production of NaOH gives less CO2 emission compared to Na2SiO3, which requires higher calcination temperatures for Na2CO3 and SiO2. However, their usage is considered unsustainable due to their caustic nature, high energy demand, and cost. Besides the blending of fly ash with other industrial by-products, phosphogypsum also has the potential for use as an ingredient in blended geopolymer systems. The parameters identified in this review can help foster the robust adoption of geopolymer as a potential “go-to” alternative to ordinary Portland cement for construction. Furthermore, the proposed future research areas will help address the various innovation gaps observed in current literature with a view of the environment and society.

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“…Geopolymer is an aluminosilicate material with a three-dimensional amorphous structure formed by alkali-excited active aluminosilicate minerals, and the reaction process is called alkali-excited geopolymerization. , Compared with the current common utilization methods, the comprehensive utilization of phosphate mine solid waste by the alkali-excited geopolymerization reaction is a new sustainable method that can treat phosphorus tailings, phosphogypsum, and yellow phosphorus slag in a low-cost and environment-friendly way, which can turn them into treasures and improve the comprehensive utilization rate of phosphate mine solid waste. − Geopolymer is an environmentally friendly cementitious material with good mechanical properties, which can dissipate a large amount of solid waste and is used in different fields as a substitute for ordinary silicate cement. , Li et al investigated the effects of blending gypsum dihydrate, flue gas desulfurization gypsum, and phosphogypsum on the compatibility and mechanical properties of red mud slag slurry materials with different gypsum contents. Shi et al added modified quartz sand to the phosphogypsum cementitious filling slurry, which can effectively improve the phosphate contamination in the process of phosphogypsum cementation and filling.…”

Section: Introductionmentioning

confidence: 99%

“… 11 , 12 Compared with the current common utilization methods, the comprehensive utilization of phosphate mine solid waste by the alkali-excited geopolymerization reaction is a new sustainable method that can treat phosphorus tailings, phosphogypsum, and yellow phosphorus slag in a low-cost and environment-friendly way, which can turn them into treasures and improve the comprehensive utilization rate of phosphate mine solid waste. 13 − 16 Geopolymer is an environmentally friendly cementitious material with good mechanical properties, which can dissipate a large amount of solid waste and is used in different fields as a substitute for ordinary silicate cement. 17 , 18 Li et al 19 investigated the effects of blending gypsum dihydrate, flue gas desulfurization gypsum, and phosphogypsum on the compatibility and mechanical properties of red mud slag slurry materials with different gypsum contents.…”

Section: Introductionmentioning

confidence: 99%

Effect of Synergistic Modification of Building Materials Based on α-Hemihydrate Phosphogypsum by Portland Cement/H-PDMS on Water Resistance

et al. 2022

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Alpha-hemihydrate phosphogypsum (α-HPG) is a cementitious material obtained by dehydration of phosphogypsum (PG), a byproduct of phosphoric acid production. Poor water resistance of α-HPG has usually restricted its application in construction materials. In this study, hydroxy-terminated polydimethylsiloxane (H-PDMS) and Portland cement (PC) were used for the hydrophobic modification of α-HPG. The fluidity, setting times, compressive strength, flexural strength, ratio of compressive to flexural strength, water absorption rate, softening coefficient, pore structure, chemical information, and microstructure of the samples were measured to evaluate the modification effect of H-PDMS and PC. The results showed that H-PDMS and PC significantly improved waterproof properties of α-HPG and reduced its porosity, total pore area, and pore diameter. Specifically, PC provided the reactive group −OH that reacted with H-PDMS. Also, due to the coverage of hydrophobic −CH3 groups, PG was given an overall hydrophobicity with a contact angle of 134° (1.5% H-PDMS). H-HPG (H-PDMS- and PC-modified α-HPG) hydrophobic material can be used in building materials with waterproof requirements and achieve the comprehensive utilization of solid waste PG.

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Alkaline Activation of Basic Oxygen Furnace Slag Modified Gold Mine Tailings for Building Material

Cited by 16 publications

References 49 publications

One part alkali activated materials: A state-of-the-art review

One part alkali activated materials: A state-of-the-art review

Geopolymer: A Systematic Review of Methodologies

Effect of Synergistic Modification of Building Materials Based on α-Hemihydrate Phosphogypsum by Portland Cement/H-PDMS on Water Resistance

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