Removal of dye AG25 by a hybrid process of plasma-activated water and cobalt nanoferrite photocatalysis: part I

Cobalt nanoferrite CoFe 2 O 4 (NFCo) was synthesized using the sol–gel auto-combustion method. The structural, morphology, and magnetic properties were characterized. X-ray diffraction analysis revealed the formation of a pure phase with an inverse spinel structure, featuring an average crystallite...

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Veröffentlicht in:	Journal of nanoparticle research : an interdisciplinary forum for nanoscale science and technology 2024-07, Vol.26 (7), p.169, Article 169
Hauptverfasser:	Benkrifa, Fatima Z., Abdelmalek, Fatiha, Sabri, Khelifa, Hachemi, Chaimaa, Taibi, Kamel, Addou, Ahmed
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Schlagworte:	Arc discharges Catalysts Characterization and Evaluation of Materials Chemistry and Materials Science Cobalt Cobalt ferrites Coercivity Crystallites Crystals Decoloring Decolorization Dyes Electric arcs Gliding Hybrid systems Inorganic Chemistry Lasers Magnetic properties Materials Science Morphology Nanotechnology Optical Devices Optics Oxidation resistance pH effects Photocatalysis Photonics Physical characteristics Physical Chemistry Raman spectroscopy Scanning electron microscopy Sol-gel processes Spectroscopic analysis Spectroscopy Spectrum analysis Spinel Ultraviolet radiation Vibration mode Water discharge Water pollution Water treatment X-ray diffraction
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description	Cobalt nanoferrite CoFe 2 O 4 (NFCo) was synthesized using the sol–gel auto-combustion method. The structural, morphology, and magnetic properties were characterized. X-ray diffraction analysis revealed the formation of a pure phase with an inverse spinel structure, featuring an average crystallite size of 67 nm. Scanning electron microscopy observations revealed the existence of particle agglomerates and a porous morphology. The spinel structure was confirmed by Raman spectroscopy, with the identification of the five characteristic modes (A 1g (1) , E g , T 2g (3) , T 2g (2) , T 2g (1) ), as well as by FTIR spectroscopy, where the two vibrational modes in the tetrahedral and octahedral sites (576.8 and 412.12 cm −1 ) were observed. Magnetic analysis revealed that the coercive field increased resistance to demagnetization. Various oxidation processes, including UV, plasma-activated water (PAW) by gliding arc discharge (GAD), and NFCo, as well as hybrid systems UV, PAW/UV, NFCo/UV, PAW/NFCo, and PAW/NFCo/UV, were employed to assess the elimination of AG25 dye. Decolorization processes, mechanisms, and photocatalysis were studied. The effect of experimental parameters as a function of time, pH, and UV exposure showed that the maximum decolorization rate was 56.1% with PAW alone, 73.1% with PAW/UV, 72.4% with PAW/NFCo, and 99.1% with PAW/NFCo/UV after 360 min. The effect of pH demonstrated that the treatment is more effective under acidic conditions (pH = 2), achieving a decolorization rate of 75.6% in just 60 min, compared to neutral and alkaline conditions. This study underscores the potential of NFCo combined with plasma-activated water and UV as magnetic nanophotocatalysts to replace classical heterogeneous catalysts in water treatment, offering new perspectives for more effective methods of degrading organic pollutants in water treatment applications.
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Decolorization processes, mechanisms, and photocatalysis were studied. The effect of experimental parameters as a function of time, pH, and UV exposure showed that the maximum decolorization rate was 56.1% with PAW alone, 73.1% with PAW/UV, 72.4% with PAW/NFCo, and 99.1% with PAW/NFCo/UV after 360 min. The effect of pH demonstrated that the treatment is more effective under acidic conditions (pH = 2), achieving a decolorization rate of 75.6% in just 60 min, compared to neutral and alkaline conditions. 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The structural, morphology, and magnetic properties were characterized. X-ray diffraction analysis revealed the formation of a pure phase with an inverse spinel structure, featuring an average crystallite size of 67 nm. Scanning electron microscopy observations revealed the existence of particle agglomerates and a porous morphology. The spinel structure was confirmed by Raman spectroscopy, with the identification of the five characteristic modes (A 1g (1) , E g , T 2g (3) , T 2g (2) , T 2g (1) ), as well as by FTIR spectroscopy, where the two vibrational modes in the tetrahedral and octahedral sites (576.8 and 412.12 cm −1 ) were observed. Magnetic analysis revealed that the coercive field increased resistance to demagnetization. Various oxidation processes, including UV, plasma-activated water (PAW) by gliding arc discharge (GAD), and NFCo, as well as hybrid systems UV, PAW/UV, NFCo/UV, PAW/NFCo, and PAW/NFCo/UV, were employed to assess the elimination of AG25 dye. Decolorization processes, mechanisms, and photocatalysis were studied. The effect of experimental parameters as a function of time, pH, and UV exposure showed that the maximum decolorization rate was 56.1% with PAW alone, 73.1% with PAW/UV, 72.4% with PAW/NFCo, and 99.1% with PAW/NFCo/UV after 360 min. The effect of pH demonstrated that the treatment is more effective under acidic conditions (pH = 2), achieving a decolorization rate of 75.6% in just 60 min, compared to neutral and alkaline conditions. 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subjects	Arc discharges Catalysts Characterization and Evaluation of Materials Chemistry and Materials Science Cobalt Cobalt ferrites Coercivity Crystallites Crystals Decoloring Decolorization Dyes Electric arcs Gliding Hybrid systems Inorganic Chemistry Lasers Magnetic properties Materials Science Morphology Nanotechnology Optical Devices Optics Oxidation resistance pH effects Photocatalysis Photonics Physical characteristics Physical Chemistry Raman spectroscopy Scanning electron microscopy Sol-gel processes Spectroscopic analysis Spectroscopy Spectrum analysis Spinel Ultraviolet radiation Vibration mode Water discharge Water pollution Water treatment X-ray diffraction
title	Removal of dye AG25 by a hybrid process of plasma-activated water and cobalt nanoferrite photocatalysis: part I
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