Mine Clay Washing Residues as a Source for Alkali-Activated Binders

Sgarlata, Caterina; Formia, Alessandra; Siligardi, Cristina; Ferrari, Francesco; Leonelli, Cristina

doi:10.3390/ma15010083

Cited by 13 publications

(2 citation statements)

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“…In this paragraph we present the recent results proving the feasibility of low-cost aluminosilicate powder as base for the formulation of a geopolymer capable of encapsulating a large number of contaminants present in one real waste from the leather industry: Cr-bearing wastewater of the tannery process rich also in Cl 1and SO 4 2anions. The novel experimental results presented hereafter are related to one formulation where a clayey mining by-product (Sgarlata et al, 2022) totally replaced a commercial metakaolin (Argical ™ M1000, produced by Imerys, France) with quartz, muscovite/ illite, and anatase as principal crystalline phases and 55-59 wt% SiO 2 , 34-40 wt% Al 2 O 3 as major chemical constituents, D90 = 40 ± 2 µm (complete particle size distribution curves are presented in Supplementary Figure S1), and surface area = 18 ± 2 m 2 /g. The mining clayey by-product was the result of an efficient industrial waste recovery process for reuse as secondary raw materials mined in Lazio, in the province of Latina, Italy.…”

Section: Direct Geopolymerization Of Cr-bearing Wastewater From Tanne...mentioning

confidence: 99%

Sustainable Chromium Encapsulation: Alkali Activation Route

Sgarlata

Leonelli²,

Lancellotti³

et al. 2022

Front. Mater.

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This article highlights recent experimental advances in the use of inorganic substances in the encapsulation of pollutants and, in particular, discusses the potential applicability and constraints of the geopolymerization process for the treatment of wastewater containing chromium. A great percentage of waste containing chromium salts is produced by the leather industry during the tannery process. Such industrial waste is in the form of liquor containing almost 40% of the initial chromium combined with many other pollutants. The stabilization/solidification (S/S) treatment of this type of waste must be combined with chromium encapsulation in an economic, environmentally friendly and efficient process to be industrially feasible. Here we present a novel process in which the wastewater is used as a component of the formulation together with a clay by-product and with the addition of NaOH pellets with the goal of a no-water plus no-waste technology approach. The final solidified “ceramic-like” material successfully immobilized the heavy metal cations as well as anions and macromolecules of surfactants, avoiding environmental damages to soil and groundwater. The article is completed by mentioning other S/S processes where wastewater has been treated and the resulting sludge encapsulated. The future of the S/S technologies in the tannery industry should progress in the direction of significantly reducing the amount of wastewater directed to the treatment plants, with associated reductions in transport and their CO2 emissions. This article intends to be a contribution in the direction of preventing waste, aligning circular economy and waste management objectives.

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Section: Direct Geopolymerization Of Cr-bearing Wastewater From Tanne...mentioning

confidence: 99%

Sustainable Chromium Encapsulation: Alkali Activation Route

Sgarlata

Leonelli²,

Lancellotti³

et al. 2022

Front. Mater.

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“…In addition, their manufacturing process consumes less energy and emits less CO 2 than the ordinary Portland cement (OPC) manufacturing process; thus, geopolymers have attracted considerable research attention and have been regarded as a potential alternative to OPC for preparing concrete materials [ 10 , 11 , 12 ]. Raw materials with sufficient amounts of reactive alumina and silica (such as clay minerals [ 13 , 14 ], solid waste [ 15 , 16 , 17 ], and other minerals [ 18 , 19 ]) and solid wastes such as mine tailings [ 17 , 20 ], fly ash (FA) [ 21 , 22 ], and slag [ 23 , 24 ] can be directly used as geopolymer precursors. In particular, finding use for solid waste in the concrete industry promotes environmental protection.…”

Section: Introductionmentioning

confidence: 99%

Effect of Magnesium Salt (MgCl2 and MgSO4) on the Microstructures and Properties of Ground Granulated Blast Furnace Slag (GGBFS)-Based Geopolymer

et al. 2022

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The use of seawater to prepare geopolymers has attracted significant research attention; however, the ions in seawater considerably influence the properties of the resulting geopolymers. This study investigated the effects of magnesium salts and alkaline solutions on the microstructure and properties of ground-granulated-blast-furnace-slag-based geopolymers. The magnesium salt–free Na2SiO4-activatied geopolymer exhibited a much higher 28 d compressive strength (63.5 MPa) than the salt-free NaOH-activatied geopolymer (31.4 MPa), with the former mainly containing an amorphous phase (C-(A)-S-H gel) and the latter containing numerous crystals. MgCl2·6H2O addition prolonged the setting times and induced halite and Cl-hydrotalcite formation. Moreover, mercury intrusion porosimetry and scanning electron microscopy revealed that the Na2SiO4-activated geopolymer containing 8.5 wt% MgCl2·6H2O exhibited a higher critical pore size (1624 nm) and consequently, a lower 28 d compressive strength (30.1 MPa) and a more loosely bound geopolymer matrix than the salt-free geopolymer. In contrast, MgSO4 addition had less pronounced effects on the setting time, mineral phase, and morphology. The Na2SiO4-activated geopolymer with 9.0 wt% MgSO4 exhibited a compressive strength of 42.8 MPa, also lower than that of the salt-free geopolymer. The results indicate that Cl− is more harmful to the GGBFS-based geopolymer properties and microstructure than SO42− is.

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