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Ceftriaxone photodegradation in wastewater using AgCuFe2O4/ZnO Almond-like heterogeneous nanocatalyst anchored on multi walled carbon nanotubes: Synthesis, characterization, mechanism study, and bioassay effluent

Zahra Sabok-khiz, Alireza Nasiri, Hasti Daraei

2024Environmental Technology & Innovation45 citationsDOIOpen Access PDF

Abstract

This study investigated the Ceftriaxone (CFT) degradation by photocatalytic process using AgCuFe 2 O 4 @MWCNT/ZnO as novel nanophotocatalyst. Firstly, the catalyst was prepared by microwave-assisted chemical coprecipitation method as a simple, fast, and green procedure with high efficiency. FESEM, EDS, Mapping, Line scan, FTIR, XRD, BET, DRS, PL, TGA, and VSM analyzes was carried out to identify the characteristics of the AgCuFe 2 O 4 @MWCNT/ZnO. The effect of key operational parameters for CFT photodegradation including solution pH, catalyst dosage, CFT concentration, and irradiation time was elaborated. Under optimal photocatalytic conditions (pH 7, 5 mg/L of CFT concentration, catalyst dosage of 0.24 g/L, and 60 minutes of irradiation) removal efficiency reached 90.1 % in synthetic samples and 75 % in real wastewater samples. • OH and • O 2 – are the dominant generated reactive oxygen species in the process. The kinetic study of the process revealed that the CFT degradation process followed the pseudo -first-order kinetic and Langmuir-Hinshelwood models with k c = 0.412 mg/L.min and k L-H =0.053 L/mg. Photocatalytic process indicated a powerful ability for mineralization of CFT (85.31 % of COD degradation). After four catalyst recovery cycles, the CFT degradation efficiency was achieved by 58.14 %, demonstrating the catalyst's recovery capability and chemical stability. The results of toxicity assessment using lettuce and basil seeds germination indicated a significant detoxification of CFT-containing effluent compared to the untreated CFT-containing wastewater. This study offers AgCuFe 2 O 4 @MWCNT/ZnO as effective, stable, and competitive catalyst for hastening and enhancing the photocatalytic process to mitigate environmentally related pollutants of high concern. • AgCuFe2O4@MWCNT/ZnO was synthesized by a simple, fast, and high-efficient microwave-assisted chemical coprecipitation method. • Catalyst was characterized by FESEM, EDS, Mapping, Line scan, FTIR, XRD, BET, DRS, PL, TGA, and VSM technique. • AgCuFe2O4@MWCNT/ZnO was employed as an efficient environmentally friendly photocatalyst for Ceftriaxone degradation. • Photocatalyst magnetically recovered and indicated high activity and stability after 4 cycles of reusability experiments. • The detoxification of effluent containing Ceftriaxone by photocatalytic process using AgCuFe2O4@MWCNT/ZnO was experimented.

Topics & Concepts

BioassayPhotodegradationEffluentWastewaterCarbon nanotubeChemistryCharacterization (materials science)Environmental chemistryPulp and paper industryMaterials scienceNanotechnologyEnvironmental sciencePhotocatalysisCatalysisEnvironmental engineeringOrganic chemistryBiologyEcologyEngineeringAdvanced Photocatalysis TechniquesNanomaterials for catalytic reactionsCopper-based nanomaterials and applications
Ceftriaxone photodegradation in wastewater using AgCuFe2O4/ZnO Almond-like heterogeneous nanocatalyst anchored on multi walled carbon nanotubes: Synthesis, characterization, mechanism study, and bioassay effluent | Litcius