Groundwater treatment and disinfection by electrochemical advanced oxidation process: Influence of the supporting electrolyte and the nature of the contaminant

The United Nations (UN) has considered water a human right since 1977. However, freshwater available for consumption represents less than 1% of all water on Earth. Groundwater represents one of the largest reserves of drinking water and is susceptible to chemical contamination, especially from pollu...

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Bibliographic Details
Published in:Applied Research 2024-04, Vol.3 (2), p.n/a
Main Authors: Soares, Beatriz S., Mello, Rodrigo, Motheo, Artur J.
Format: Article
Language:English
Subjects:
Anodizing
Atrazine
Bacteria
Bisphenol A
Boron
boron doped diamond anode
Chemical contaminants
Chemical contamination
Chemical pollution
Chemical treatment
Contaminants
Contamination
Degradation
Drinking behavior
Drinking water
E coli
Efficiency
electrochemical advanced oxidation process
Electrochemical oxidation
Electrochemistry
Electrolysis
emerging pollutants
Escherichia coli disinfection
Groundwater
Groundwater treatment
Herbicides
Impact analysis
Impurities
Mineralization
Nitrates
Oxidation
Oxidation process
Pattern analysis
Soil chemistry
Soil contamination
Soil pollution
Soil water
supporting electrolyte
Water analysis
Water sampling
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Summary:The United Nations (UN) has considered water a human right since 1977. However, freshwater available for consumption represents less than 1% of all water on Earth. Groundwater represents one of the largest reserves of drinking water and is susceptible to chemical contamination, especially from pollutants that seep into the soil, such as atrazine, bisphenol A, and tetracycline. These substances, along with Escherichia coli, were selected to simulate contamination in groundwater samples and evaluate the efficiency of electrochemical oxidation using boron‐doped diamond anodes and four different anion salts to analyze their impact on the treatment process. After electrolysis, the degradation of tetracycline, bisphenol A and atrazine was found to increase with decreasing current density, with average values of 77%, 96% and 100% at 15 mA cm−2 and 68%, 83% and 99% at 35 mA cm−2, respectively. Moreover, the mineralization of these substances showed the same behavior, decreasing from 67%, 64%, and 54% at 15 mA cm−2 to 52%, 35%, and 49% at 35 mA cm−2. The analysis of the results showed that the ions present in the solution significantly affect the degradation process and that they interact with the impurities used. For atrazine and tetracycline, the degradation efficiency followed the same pattern, PO 4 3 − ${{\mathrm{PO}}_{4}}^{3-}$ 
ISSN:2702-4288
2702-4288
DOI:10.1002/appl.202300008