Reduction of Toxic Metal Ions and Production of Bioelectricity through Microbial Fuel Cells Using Bacillus marisflavi as a Biocatalyst

Industrialization has brought many environmental problems since its expansion, including heavy metal contamination in water used for agricultural irrigation. This research uses microbial fuel cell technology to generate bioelectricity and remove arsenic, copper, and iron, using contaminated agricult...

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Bibliographic Details
Published in:Molecules (Basel, Switzerland) Switzerland), 2024-06, Vol.29 (12), p.2725
Main Authors: Segundo, Rojas-Flores, De La Cruz-Noriega, Magaly, Luis, Cabanillas-Chirinos, Otiniano, Nélida Milly, Soto-Deza, Nancy, Rojas-Villacorta, Walter, De La Cruz-Cerquin, Mayra
Format: Article
Language:English
Subjects:
agricultural wastewater
Arsenic
Arsenic - metabolism
Bacillus - metabolism
Bacteria
Biocatalysts
Biodegradation, Environmental
Bioelectric Energy Sources - microbiology
bioelectricity
Biofilms
Bioremediation
Carbon
Catalysts
Chemical oxygen demand
Copper - chemistry
Copper - metabolism
Electric currents
Electricity generation
Electrodes
Food contamination & poisoning
Fruits
Fuel cell industry
Fuel cells
Heavy metals
Hydrogen-Ion Concentration
Metals, Heavy
microbial fuel cells
Microorganisms
Purification
removal
Rivers
Sewage
Wastewater
Water Pollutants, Chemical - metabolism
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Summary:Industrialization has brought many environmental problems since its expansion, including heavy metal contamination in water used for agricultural irrigation. This research uses microbial fuel cell technology to generate bioelectricity and remove arsenic, copper, and iron, using contaminated agricultural water as a substrate and as a biocatalyst. The results obtained for electrical potential and current were 0.798 V and 3.519 mA, respectively, on the sixth day of operation and the pH value was 6.54 with an EC equal to 198.72 mS/cm, with a removal of 99.08, 56.08, and 91.39% of the concentrations of As, Cu, and Fe, respectively, obtained in 72 h. Likewise, total nitrogen concentrations, organic carbon, loss on ignition, dissolved organic carbon, and chemical oxygen demand were reduced by 69.047, 86.922, 85.378, 88.458, and 90.771%, respectively. At the same time, the PD shown was 376.20 ± 15.478 mW/cm , with a calculated internal resistance of 42.550 ± 12.353 Ω. This technique presents an essential advance in overcoming existing technical barriers because the engineered microbial fuel cells are accessible and scalable. It will generate important value by naturally reducing toxic metals and electrical energy, producing electric currents in a sustainable and affordable way.
ISSN:1420-3049
1420-3049
DOI:10.3390/molecules29122725