Recent advances in antimony removal using carbon-based nanomaterials: A review

Recently, special attention has been deserved to environmental risks of antimony (Sb) element that is of highly physiologic toxicity to human. Conventional coagulation and ion exchange methods for Sb removal are faced with challenges of low efficiency, high cost and secondary pollution. Adsorption based on carbon nanomaterials (CNMs; e.g., carbon nanotubes, graphene, graphene oxide, reduced graphene oxide and their derivatives) may provide effective alternative because the CNMs have high surface area, rich surface chemistry and high stability. In particular, good conductivity makes it possible to create linkage between adsorption and electrochemistry, thereby the synergistic interaction will be expected for enhanced Sb removal. This review article summarizes the state of art on Sb removal using CNMs with the form of nano-adsorbents and/or filtration membranes. In details, procedures of synthesis and functionalization of different forms of CNMs were reviewed. Next, adsorption behavior and the underlying mechanisms toward Sb removal using various CNMs were presented as resulting from a retrospective analysis of literatures. Last, we prospect the needs for mass production and regeneration of CNMs adsorbents using more affordable precursors and objective assessment of environmental impacts in future studies. (c) Higher Education Press 2021

Automated summary

Recent attention has been focused on the environmental risks posed by the highly toxic antimony (Sb) element to human health. Traditional methods for Sb removal face challenges of low efficiency, high costs, and potential secondary pollution. Carbon nanomaterials offer a promising alternative due to their high surface area, rich surface chemistry, and stability. Good conductivity of CNMs allows for a synergistic interaction between adsorption and electrochemistry, enhancing Sb removal efficiency.