Synthesis of kaolin supported nanoscale zero-valent iron and its degradation mechanism of Direct Fast Black G in aqueous solution

UV–visible spectra of DFBG solution using K-nZVI (1:1) nanoparticles. (a) Before reaction; (b) during reaction; (c) after reaction. [Display omitted] •Kaolin-supported Fe0 nanoparticle (K-nZVI) was synthesized.•Degradation of Direct Fast Black by K-nZVI was studied.•K-nZVI was characterized by SEM,...

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Bibliographic Details
Published in:Materials research bulletin 2015-01, Vol.61, p.433-438
Main Authors: Jin, Xiaoying, Chen, Zhengxian, Zhou, Rongbing, Chen, Zuliang
Format: Article
Language:English
Subjects:
A. Magnetic materials
A. Nanostructures
ADSORPTION
AQUEOUS SOLUTIONS
B. Chemical synthesis
CONCENTRATION RATIO
D. Catalytic properties
FOURIER TRANSFORMATION
INFRARED SPECTRA
IRON
IRON OXIDES
KAOLIN
MAGNETIC MATERIALS
MATERIALS SCIENCE
NANOPARTICLES
NANOSTRUCTURES
REACTIVITY
SCANNING ELECTRON MICROSCOPY
SYNTHESIS
ULTRAVIOLET SPECTRA
VISIBLE SPECTRA
X-RAY DIFFRACTION
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Summary:UV–visible spectra of DFBG solution using K-nZVI (1:1) nanoparticles. (a) Before reaction; (b) during reaction; (c) after reaction. [Display omitted] •Kaolin-supported Fe0 nanoparticle (K-nZVI) was synthesized.•Degradation of Direct Fast Black by K-nZVI was studied.•K-nZVI was characterized by SEM, XRD, UV and FIIR.•Degradation mechanism of Direct Fast Black was proposed. Calcinated kaolin supported nanoscale zero-valent iron (K-nZVI) was synthesized and used for the removal of tetrad azo-group dye-Direct Fast Black G (DFBG) from aqueous solution. The results demonstrated that after reacting for 10min with an initial concentration of DFBG 100mgL−1 (pH 9.49), 78.60% of DFBG was removed using K-nZVI, while only 41.39% and 12.56% of DFBG were removed using nZVI and kaolin, respectively. K-nZVI with a mass ratio of nZVI nanoparticles versus kaolin at 1:1 was found to have a high degree of reactivity. Furthermore, scanning electron microscopy (SEM) confirmed that nZVI was better dispersed when kaolin was present. XRD patterns indicated that iron oxides were formed after reaction. Fourier transforms infrared spectra (FTIR) and UV–visible demonstrated that the peak in the visible light region of DFBG was degraded and new bands were observed. Kinetics studies showed that the degradation of DFBG fitted well to the pseudo first-order model. The degradation of DFBG by K-nZVI was based on its adsorption onto kaolin and iron oxides, and subsequently reduction using nZVI was proposed. A significant outcome emerged in that 99.84% of DFBG in wastewater was removed using K-nZVI after reacting for 60min.
ISSN:0025-5408
1873-4227
DOI:10.1016/j.materresbull.2014.10.057