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- Title
Removal of Methyl Orange in Aqueous Solutions Using Hydrochloric Acid-Modified Kaolinite Supported Nanosized Zero-Valent Iron.
- Authors
Tan, Yunfeng; Zhang, Yangyang; Zu, Bo; Zhang, Yunxia; Zheng, Chunli; Chen, Kejun
- Abstract
This study presents an efficient application of the Fenton reaction for the degradation of methyl orange (MO), utilizing a composite of hydrochloric acid-modified kaolinite supported nanosized zero-valent iron (mk-nZVI). The successful loading of Fe0 onto the hydrochloric acid–modified kaolinite was confirmed through scanning electron microscopy, X-ray diffraction, and Fourier transform infrared spectroscopy analyses. Key variables, such as solution pH, reaction temperature, mk-nZVI dose, initial MO solution concentration, and H2O2 concentration, were manipulated to examine the efficacy of the mk-nZVI/H2O2 system in the degradation of MO. The system demonstrated improved degradation performance with decreased pH and increased temperature. Under the following conditions: an initial pH of 5.6, a reaction temperature of 25 °C, an mk-nZVI dose of 2 g/L, an initial MO solution concentration of 100 mg/L, and an H2O2 concentration of 74.8 mmol/L, an MO degradation of 96.56% was achieved using the mk-nZVI/H2O2-based Fenton-like reaction. This performance was markedly superior to the traditional Fenton method in decolorizing MO solutions. UV–Vis spectroscopy demonstrated the mk-nZVI/H2O2-based Fenton-like reaction's effectiveness in degrading MO's azo structure. The degradation of MO was primarily attributed to the action of surface-bounded hydroxyl radicals. The findings indicate that the synthesized mk-nZVI composite holds promise for efficient treatment of MO in water, establishing it as a prospective composite material for wastewater remediation.
- Subjects
KAOLINITE; FOURIER transform infrared spectroscopy; AQUEOUS solutions; HABER-Weiss reaction; IRON
- Publication
Water, Air & Soil Pollution, 2023, Vol 234, Issue 7, p1
- ISSN
0049-6979
- Publication type
Article
- DOI
10.1007/s11270-023-06417-2