Enhanced Oxidation of Organic Contaminants by Mn(VII)/CaSO3 Under Environmentally Relevant Conditions: Performance and Mechanisms

Although permanganate activation by sodium sulfite (Mn(VII)/Na2SO3) has shown great potential for rapid abatement of organic contaminants, the limited reactivity under alkaline conditions and undesirable Mn residual may prevent its widespread application. To solve these challenges, calcium sulfite (CaSO3) was employed as a slow-release source of SO32-/HSO3- (S(IV)) to activate Mn(VII) in this study. It was found that the application of CaSO3 solid could extend the effective working pH range of Mn(VII)/S(IV) from <= 7.0 to <= 9.0. Moreover, due to the enhanced precipitation of MnO2 with the presence of Ca2+, very low Mn residual (< 0.05 mg/L) was achieved in Mn(VII)/CaSO3 system. Mn(VII)/CaSO3 system is a unique two-stage oxidation process in terms of reaction kinetics and reactive oxidants. Specifically, Mn(VII) was rapidly consumed and reactive Mn intermediates (e.g., Mn(VI), Mn(V)), SO4 center dot- , and HO center dot were produced in the first stage. However, the second stage was governed by the interaction between MnO2 and S(IV), with SO4 center dot- and HO center dot serving as the dominant reactive oxidants. Taking advantage of an automatic titrator, excess S(IV) was found to greatly quench the generated radicals, whereas it did not cause a significant consumption of reactive Mn species. All these results improved our understanding of the Mn(VII)/S(IV) process and could thus facilitate its application. (C) 2020 Elsevier Ltd. All rights reserved.

Automated summary

Using calcium sulfite as a slow-release source of sulfur dioxide, the effective working pH range of permanganate activation by sodium sulfite was extended from <= 7.0 to <= 9.0. The presence of calcium ions in the system led to enhanced precipitation of manganese dioxide, resulting in very low residual manganese levels. The Mn(VII)/CaSO3 system demonstrated a unique two-stage oxidation process with improved understanding of reaction kinetics and reactive oxidants.