Effect of Si/Al molar ratio on the immobilization of selenium and arsenic oxyanions in geopolymer

The effect of Si/Al molar ratio of geopolymer on the immobilization of Se and As oxyanions was studied through leaching test and solid characterizations including XRD, FTIR, TG, NMR, XAFS, and N-2 adsorption-desorption isotherm. As a whole, the leaching percentages of Se and As oxyanions increased with the increase of the Si/Al molar ratio of geopolymer. Linear combination fitting confirmed that most of selenite, selenate and arsenate ions existed in geopolymers through electrostatic interaction. Thus, Al tetrahedrons in geopolymer structure control the charge stability for these oxyanions to a large extent. Differently, as for arsenate ions, they were recrystallized into an arsenate compound (Na-3.25(OH)(0.25)(H2O)(12))(AsO4) in geopolymers. The additive of these pollutants has an adverse effect on the compactness of geopolymer, then influencing the leaching performance in turn. However, the changes in leaching results did not follow the variation trend of specific surface areas and pore volumes of geopolymers with different Si/Al ratios. The number and distribution of Al tetrahedron and compactness of geopolymer have a synergistic effect on the immobilization of these oxyanions. Besides, the compressive strengths of geopolymer samples are always higher than 20 MPa, which meets the requirement of safe disposal of hazardous waste. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

The Si/Al molar ratio of geopolymer has an impact on the immobilization of Se and As oxyanions, with Al tetrahedrons playing a key role in the geopolymer structure. The addition of pollutants affects the compactness and leaching performance of geopolymer. The compressive strength of geopolymer samples is always higher than 20 MPa, meeting the requirement for the safe disposal of hazardous waste.