Arsenic sequestration by iron oxide coated geopolymer microspheres

A green, low-cost adsorbent based on geopolymer microspheres is reported for the first time for arsenic adsorption. A simple two-step process involves synthesizing geopolymer microspheres by inverse suspension polymerization and impregnating them with iron oxide. The low hydraulic conductivity of fine iron oxide powders demands the use of suitable support materials. Iron oxide modified geopolymer microparticles synthesized here, are small, spherical, porous, mechanically, and chemically stable, have high surface area of 270 m(2)/g and can be easily separated from water after adsorption is complete. A comprehensive adsorption study was conducted by employing environmentally critical arsenic species, viz. As(III), As(V), monomethyl arsenate and dimethyl arsenate. The role of contact time, initial arsenic concentration, temperature, adsorbent dosage, pH and competing ions was evaluated. Highest arsenic adsorption was observed at an iron content of 20 wt%. High percent removal of similar to 86%, 100%, 95% and 96% for As(III), As(V), DMA and MMA respectively, were observed at initial arsenic concentration of 0.5 mg/L, an adsorbent dosage of 10 g/L and in just 60 min. Low pH favored adsorption of As(V), monomethyl arsenate and dimethyl arsenate while high pH favored adsorption of As(III). The applicability of the novel adsorbent in column mode, its high regeneration capacity and, facile, green, and cheap production are few of its advantages. Moreover, unmodified geopolymer microspheres, introduced here, can be employed as adsorbents for other toxic heavy metals such as Pb, Cd and Hg. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

A green, low-cost adsorbent based on geopolymer microspheres was reported for arsenic adsorption for the first time. The iron oxide modified geopolymer microparticles showed excellent arsenic adsorption performance, especially with high removal rates for different arsenic species under specific conditions.