Simultaneous immobilization strategy of anionic metalloids and cationic metals in agricultural systems: A review

Khadeza YASMIN, Md. Shahadat HOSSAIN, Wai Chin LI

Research output: Contribution to journalArticlespeer-review

Abstract

Concurrent heavy metals remediation in natural environments poses significant challenges due to factors like metal speciation and interactions with soil moisture. This review focuses on strategies for immobilizing both anionic and cationic metals simultaneously in soil-crop systems. Key approaches include water management, biochar utilization, stabilizing agents, nanotechnology, fertilization, and bioremediation. Sprinkler or intermittent irrigation combined with soil amendments/biochar effectively immobilizes As/Cd/Pb simultaneously. This immobilization occurs through continuous adsorption-desorption, oxidation-reduction, and precipitation mechanisms influenced by soil pH, redox reactions, and Fe-oxides. Biochar from sources like wine lees, sewage sludge, spent coffee, and Fe-nanoparticles can immobilize As/Cd/Pb/Cr/Co/Cu/Zn together via precipitation. In addition, biochar from rice, wheat, corn straw, rice husk, sawdust, and wood chips, modified with chemicals or nanoparticles, simultaneously immobilizes As and Cd, containing higher Fe3O4, Fe-oxide, and OH groups. Ligand exchange immobilizes As, while ion exchange immobilizes Cd. Furthermore, combining biochar especially with iron, hydroxyapatite, magnetite, goethite, silicon, graphene, alginate, compost, and microbes—can achieve simultaneous immobilization. Other effective amendments are selenium fertilizer, Ge-nanocomposites, Fe–Si materials, ash, hormone, and sterilization. Notably, combining nano-biochar with microbes and/or fertilizers with Fe-containing higher adsorption sites, metal-binding cores, and maintaining a neutral pH could stimulate simultaneous immobilization. The amendments have a positive impact on soil physio-chemical improvement and crop development. Crops enhance production of growth metabolites, hormones, and xylem tissue thickening, forming a protective barrier by root Fe-plaque containing higher Fe-oxide, restricting upward metal movement. Therefore, a holistic immobilization mechanism reduces plant oxidative damage, improves soil and crop quality, and reduces food contamination. Copyright © 2024 Elsevier Ltd.

Original languageEnglish
Article number143106
JournalChemosphere
Volume364
Early online dateAug 2024
DOIs
Publication statusPublished - 2024

Citation

Yasmin, K., Hossain, M. S., & Li, W. C. (2024). Simultaneous immobilization strategy of anionic metalloids and cationic metals in agricultural systems: A review. Chemosphere, 364, Article 143106. https://doi.org/10.1016/j.chemosphere.2024.143106

Keywords

  • Soil moisture
  • Soil biogeochemistry
  • Biochar
  • Nanoparticles
  • Remediation
  • PG student publication

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