Abstract
ABSTRACT: The high demand for concrete has triggered studies on the mitigation of Portland cement production impacts, such as greenhouse gas emissions and energy demands, in addition to enabling cost reduction. Partial replacement of cement with other materials has been employed as an alternative to minimize the damage caused by the cement industry. In this regard, it is necessary to use materials that efficiently replace cement clinker. This study uses waste generated from the production of metallic magnesium as a partial replacement for Portland cement. The substitution is aimed at reducing the amount of clinker used, as its production necessitates high energy consumption and results in emission of large quantities of CO2 into the atmosphere. The tailings were characterized via X-ray fluorescence (XRF), X-ray diffraction (XRD), scanning electron microscopy (SEM), and granulometric analysis. For evaluating the mechanical behavior and porosity, 25% of the cement (by mass) was replaced with tailings, and the resulting composite was molded into cylindrical specimens. After curing for 28 and 91 days, all specimens underwent compression testing. The results of the physical characterization showed that more than 65% of the tailing grain was lesser than 45 μm in size, which contributes to the packaging effect. In terms of the chemical and mineralogical composition, the tailing had high levels of calcium, and the predominant phases could be identified. The compressive strength of the mortar with substitution was higher than 40 MPa. The convergence observed between the results of the different characterization techniques demonstrates the efficiency of using the waste as a supplementary cementitious material.
Highlights
Climate change is directly linked to greenhouse gas concentration, which modifies the average temperature of the planet; in recent years, this has increased
Calcium silicate is present owing to the calcination processes, whereas the presence of periclase or periclase is expected as it is a material derived from dolomite; this justifies the presence of MgO in the chemical analysis of the material
The studies and tests carried out indicate the feasibility of using waste from the metal magnesium industry as a partial substitute for Portland cement
Summary
Climate change is directly linked to greenhouse gas concentration, which modifies the average temperature of the planet; in recent years, this has increased. Noteworthy partial clinker replacements include alkali-activated binders and binders based on reactive calcium silicates, magnesium oxides, precipitated calcium carbonates, and phosphates. The consumption of fly ash currently represents 70% of the volume of supplementary cement materials, totaling $75 billion in sales, and it is estimated to reach $98 billion in 2020 as a result of the high demand for materials that can partially replace clinker, reducing energy consumption and the emission of carbon dioxide. Industrial by-products are potential materials for partial replacement; these are environmentally viable, and they are considered as waste owing to their low cost [13]–[15]. Some types of binders based on magnesium silicates, amorphous calcium carbonates, and phosphates have been used in the production of cementitious materials, encouraging interest in the use of industrial residues of mineral and vegetal origin. Studies show significant results regarding the mechanical performance and durability of cementitious materials composed of industrial by-products [16]–[25]
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