AI Article Synopsis
- Electric field-assisted remediation with nano iron effectively reduces chlorinated contaminants and offers economic advantages, as shown in pilot studies.
- The process involves donating electrons to zero-valent iron, facilitating the transformation of harmful chlorinated hydrocarbons into less harmful products like ethene and ethane.
- Notably, the reduction occurs near the anode due to dissolved Fe ions, while the cathode area shows no dechlorination products, shedding light on the electrochemical dynamics of the process.
Article Abstract
Electric field assisted remediation using nano iron has shown outstanding results as well as economic benefits during pilot applications (Černíková et al., 2020). This method is based on donating electrons to the zero-valent iron that possess an inherently strong reductive capacity. The reduction of chlorinated hydrocarbons may be characterized by a decrease in contaminants or better still by the evolution of ethene and ethane originating from the reduction of chlorinated ethenes. The evolution of ethene and ethane was observed predominantly in the vicinity of the anode despite reduction processes being expected near the cathode - the electron donor. The reduction near the anode occurred due to dissolved Fe ions, whose presence was suggested by a Pourbaix diagram that combines Eh/pH values to characterize electrochemical stabilities between different species. No products of dechlorination were observed in the area of the cathode due to presence of oxidized Fe in the form of Fe or Fe(OH). The experimental work described in this research provides a deeper view of the processes of electrochemical reductive dechlorination using zero-valent iron and DC. It also showed an increase in the efficiency compared to the method using zero-valent iron only.
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| http://dx.doi.org/10.1016/j.chemosphere.2020.128764 | DOI Listing |
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