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Metallic Iron for Environmental Remediation: The Fallacy of the Electron Efficiency Concept

Rui Hu, Arnaud Igor Ndé-Tchoupé, Viet Cao, Willis Gwenzi, Chicgoua Noubactep

2021Frontiers in Environmental Chemistry28 citationsDOIOpen Access PDF

Abstract

The suitability of remediation systems using metallic iron (Fe 0 ) has been extensively discussed during the past 3 decades. It has been established that aqueous Fe 0 oxidative dissolution is not caused by the presence of any contaminant. Instead, the reductive transformation of contaminants is a consequence of Fe 0 oxidation. Yet researchers are still maintaining that electrons from the metal body are involved in the process of contaminant reduction. According to the electron efficiency concept, electrons from Fe 0 should be redistributed to: i) contaminants of concern (COCs), ii) natural reducing agents (e.g., H2O, O2), and/or iii) reducible co-contaminants (e.g. NO3 - ). The electron efficiency is defined as the fraction of electrons from Fe 0 oxidation which is utilized for the reductive transformations of COCs. This concept is in frontal contradiction with the view that Fe 0 is not directly involved in the process of contaminant reduction. This communication recalls the universality of the concept that reductive processes observed in remediation Fe 0 /H2O systems are mediated by primary (e.g., Fe II , H/H2) and secondary (e.g., Fe 3 O 4 , green rusts) products of aqueous iron corrosion. The critical evaluation of the electron efficiency concept suggests that it should be abandoned. Instead, research efforts should be directed towards tackling the real challenges for the design of sustainable Fe 0 -based water treatment systems based on fundamental mechanisms of iron corrosion.

Topics & Concepts

Environmental remediationDissolutionAqueous solutionZerovalent ironChemistryMetalContaminationElectronRedoxEnvironmental chemistryMaterials scienceChemical engineeringMetallurgyInorganic chemistryAdsorptionPhysicsOrganic chemistryEngineeringQuantum mechanicsEcologyBiologyEnvironmental remediation with nanomaterialsAdvanced oxidation water treatmentArsenic contamination and mitigation