Environmental pollution is a complex problem that threatens the health and life of animal and plant ecosystems on the planet. In this respect, the scientific community faces increasingly challenging tasks in designing novel materials with beneficial properties to address this issue. This study describes a simple yet effective synthetic protocol to obtain nickel hexacyanoferrate (Ni-HCF) nanocubes as a suitable photocatalyst, which can enable an efficient photodegradation of hazardous anthropogenic organic contaminants in water, such as antibiotics. Ni-HCF nanocubes are fully characterized and their optical and electrochemical properties are investigated. Preliminary tests are also carried out to photocatalytically remove metronidazole (MDZ), an antibiotic that is difficult to degrade and has become a common contaminant as it is widely used to treat infections caused by anaerobic microorganisms. Under simulated solar light, Ni-HCF displays substantial photocatalytic activity, degrading 94.3% of MDZ in 6 h. The remarkable performance of Ni-HCF nanocubes is attributeto a higher ability to separate charge carriers and to a lower resistance toward charge transfer, as confirmed by the electrochemical characterization. These achievements highlight the possibility of combining the performance of earth-abundant catalysts with a renewable energy source for environmental remediation, thus meeting the requirements for sustainable development.Water pollution is a threat to health and ecosystems. Nickel-hexacyanoferrate (Ni-HCF) nanocubes provide a step forward in addressing such issue, as they show excellent photocatalytic activity toward degradation of up to approximate to 94% of the antibiotic metronidazole under simulated solar light in 6 h. Superior charge carrier separation and low resistance make Ni-HCF promising for sustainable and effective environmental remediation. image

Highly Efficient Solar-Light-Driven Photodegradation of Metronidazole by Nickel Hexacyanoferrate Nanocubes Showing Enhanced Catalytic Performances

Lushaj, Edlind;Bordin, Matteo;Akbar, Kamran;Liccardo, Letizia;Vomiero, Alberto
;
Moretti, Elisa
;
Polo, Federico
2024-01-01

Abstract

Environmental pollution is a complex problem that threatens the health and life of animal and plant ecosystems on the planet. In this respect, the scientific community faces increasingly challenging tasks in designing novel materials with beneficial properties to address this issue. This study describes a simple yet effective synthetic protocol to obtain nickel hexacyanoferrate (Ni-HCF) nanocubes as a suitable photocatalyst, which can enable an efficient photodegradation of hazardous anthropogenic organic contaminants in water, such as antibiotics. Ni-HCF nanocubes are fully characterized and their optical and electrochemical properties are investigated. Preliminary tests are also carried out to photocatalytically remove metronidazole (MDZ), an antibiotic that is difficult to degrade and has become a common contaminant as it is widely used to treat infections caused by anaerobic microorganisms. Under simulated solar light, Ni-HCF displays substantial photocatalytic activity, degrading 94.3% of MDZ in 6 h. The remarkable performance of Ni-HCF nanocubes is attributeto a higher ability to separate charge carriers and to a lower resistance toward charge transfer, as confirmed by the electrochemical characterization. These achievements highlight the possibility of combining the performance of earth-abundant catalysts with a renewable energy source for environmental remediation, thus meeting the requirements for sustainable development.Water pollution is a threat to health and ecosystems. Nickel-hexacyanoferrate (Ni-HCF) nanocubes provide a step forward in addressing such issue, as they show excellent photocatalytic activity toward degradation of up to approximate to 94% of the antibiotic metronidazole under simulated solar light in 6 h. Superior charge carrier separation and low resistance make Ni-HCF promising for sustainable and effective environmental remediation. image
2024
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10278/5051702
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