Health and environment
Reza Hekmatshoar; Shahrzad Khoramnejadian; Ahmad Allahabadi; MohammadHossein Saghi
Volume 28, Issue 4 , September and October 2021, , Pages 533-544
Abstract
Introduction: Penicillin G (PG) is one of the most widely antibiotics used around the world. The release of PG in an aqueous solution leads to contamination of water resources. This study aimed to determine the efficiency of modified Eskanbil activated carbon for the removal of PG from aqueous solutions. ...
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Introduction: Penicillin G (PG) is one of the most widely antibiotics used around the world. The release of PG in an aqueous solution leads to contamination of water resources. This study aimed to determine the efficiency of modified Eskanbil activated carbon for the removal of PG from aqueous solutions. The NH4Cl-induced activated carbon was synthesized by a simple method and used for the degradation of PG in contaminated water.
Materials and Methods: Activated carbon was characterized by Fourier transform infrared spectroscopy (FTIR), Field emission scanning electron microscopy (FESEM), and Brunauer–Emmett–Teller (BET) surface area analysis. The influence of important parameters including solution pH, contact time, and initial PG concentration, and dosage of adsorbent was examined on the efficiency of EAC in degradation of penicillin G in aqueous solution.
Results: The synthesized carbon was characterized. The BET results indicated that the surface area of the Activated Carbon catalyst was1473 m2/g. The maximum PG adsorption onto EAC was observed at the pH of 6. The PG removal of 33% at an EAC concentration of 0.1 g/L increased to 99.98% at an activated carbon concentration of 0.5 g/L. The isotherm and kinetic studies of PG removal by EAC showed that the Freundlich model (R2>0.995) and the pseudo-second-order (R2>0.983) equation represented the best fit with the adsorption data.
Conclusion: EAC is recommended as a suitable and cost-efficient adsorbent for removing poisons, pharmaceuticals, and other emerging contaminants from water resources.
Health and environment
Mostafa Sobhanikia; Edris Bazrafshan; Hossein Kamani
Volume 24, Issue 2 , May and June 2017, , Pages 144-137
Abstract
Backgrounds and Objectives: Antibiotics can’t be removedefficiently by conventional wastewater treatment.Nano Zero Valent Iron (nZVI) has high efficiency of degradation of contaminants such as heavy metal, nitro aromatic compounds and insecticides. Ozonation is one of the most well known methods ...
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Backgrounds and Objectives: Antibiotics can’t be removedefficiently by conventional wastewater treatment.Nano Zero Valent Iron (nZVI) has high efficiency of degradation of contaminants such as heavy metal, nitro aromatic compounds and insecticides. Ozonation is one of the most well known methods for remove of chemichal-resistant materials like antibiotics of water and wastewater
Materials and Methods: This study is experimental. nZVI and ozonation were used to remove of penicillin G. for determination removal efficiency of penicillin, COD and TOC, factors: initial pH, dose of nano particle, initial penicillin dose, reaction time with nano particle and ozone were investigated.
Results: Removal efficiency of penicillin G, COD, TOC in stage of reaction with nZVI were 96.35%, 73.13% and 47.45%, respectivly with reaction time: 60 min, initial penicillin concentration: 100 mg/L, COD: 1429 mg/L, TOC: 510 mg/L, pH=7, nano particle iron concentration: 0.25 g/L. In the stage of reaction with ozone, removal efficiency of penicillin G, COD and TOC were 99.5%, 96.35% and 92.65%, respectivly with reaction time: 13 min, pH=9, initial penicillin 20 mg/l, COD: 356 mg/L, TOC: 136 mg/L, volumetric flow rate of ozone: 5 L/min.
Conclusion:The best removal efficiency in stage of nano particles reaction was in pH=7, initial nZVI concentration 0.25 g/L, initial penicillin concentration 100 mg/L and time about 60 min. The best removal efficiency in stage of ozonation was in pH=7 and time about 9 min.