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Enhanced in situ production of Fenton reagent's by nanobubble aeration and sacrificial iron anodes in the electro-Fenton process

siyuan he, Siao Zhao, Ziming Chen, Xiaoqiang Li, Yulong Ma, Yongsheng Ren, Xiaoxiao Duan

2023Electrochemistry Communications11 citationsDOIOpen Access PDF

Abstract

Wastewater treatment is currently focused on the development of simple, safe, cost-effective technologies for the complete destruction of persistent organic pollutants. A novel reagent-free electro-Fenton process by integrated nano-bubble aeration and sacrificial iron anode is proposed, which improves mass transferability of large content dissolved oxygen (10.55mgL-1) in the electrolyte and then quickly transported oxygen to the electrode surface. The synergistic effect of nanobubble aeration and sacrificial iron anodes can product a highly efficient hydrogen peroxide (H2O2) (310 mgL-1) and enhanced electrochemically driven reduction of Fe2+ at pH 3.5 and current density 55 mAcm-2. The degradation of phenol (100 mgL-1) with hydroxyl radicals (⋅OH) generated in situ is described by a pseudo first-order kinetics mode and was fast (0.036 min-1), which obtained a remarkable decolorization of over 58.7% in 60 min. With nanobubble aeration and sacrificial iron anode, the catalytic decomposition of H2O2 to ⋅OH by Fe2+ was more powerful, achieving a cost-effective and green design without reagents.

Topics & Concepts

AerationAnodeHydrogen peroxideChemistryReagentChemical engineeringDegradation (telecommunications)ElectrolyteCatalysisInorganic chemistryElectrodeOrganic chemistryComputer scienceEngineeringTelecommunicationsPhysical chemistryAdvanced oxidation water treatmentEnvironmental remediation with nanomaterialsMinerals Flotation and Separation Techniques
Enhanced in situ production of Fenton reagent's by nanobubble aeration and sacrificial iron anodes in the electro-Fenton process | Litcius