Abstract
A simple, economically viable and fast method has been utilized for the preparation of highly active metal nanoparticles (MNPs) in coating layer of chitosan (CH) over cellulose microfibers of cotton cloth (CC). 2 wt% of CH solution was used for the coating of CC strips (CC-CH), and were kept in aqueous solutions of metal salts to adsorb metal ions. The CC-CH templated with metal ions were then treated with aqueous solution of NaBH4 to reduce the metal ions into zero-valent metal nanoparticles (M0). The CC-CH strips loaded with M0 were characterized by XRD, XPS, ATR-FTIR, FE-SEM and TGA, which indicates the successful synthesis of MNPs by this method. The M0/CC-CH strips were used as an efficient catalyst for the model reduction reaction of nitrophenol and toxic organic dyes. Among all the prepaped samples, Fe/CC-CH showed good catalytic activity for 4-NP and Rh-B dye reduction in the presence of NaBH4 with rate constants of 0.2937 min−1 and 0.3804 min−1, respectively. Moreover Fe/CC-CH has good catalytic reduction ability for MO and MB having rate constants equal to 0.1698 and 0.2802 min−1, respectively. Beside the good catalytic ability, it could be easily recoverable as compared to other available techniques. The recovery was completed by simply pulling the strip from the reaction matrix after completion of the reaction and can be used several times.
Highlights
In recent years, the development of new catalytic system for the conversion of toxic chemicals into fine chemicals has become a foremost research area
Fourier transform infrared (FTIR), X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS) and TGA analysis confirmed that other properties of the cellulose fibers and CH did not change during the process
field emission scanning electron microscope (FESEM) and EDX analysis exposed that the Fe nanoparticles were synthesized on cotton cloth (CC)-CH strips
Summary
The intensity of the peak at 400 nm was gradually disappeared and completely vanished after 10, 12, 16, 18 and 26 min, respectively in the presence of CC-CH loaded with zero-valent Fe, Cu, Ag, Ni and Co nanoparticles (Fig. 8c and Fig. SI 2a–d) In this catalytic reduction reaction of 4-NP, the resulted increase in a new absorption band at 300 nm is recognized as the formation of 4-AP. In comparison of percent remaining concentration (%Ct/C0) of nitrophenol versus time in the presence of CC and CC-CH loaded with different M0, it can be observed that Fe/CC-CH exhibited good catalytic efficiency (Fig. 8d and f), which suggests that Fe-NPs are more active towards nitrophenols reduction These results strongly support the superior and excellent catalytic activity of the Fe nanoparticles template in thin CH layers over CC. Catalysts Fe/CC-CH Cu/ZnPc-CH Au/CA Ag/CB-CH Ag/CH-FP Au (10)/TiO2 FeNi2 alloy nanostructure Fe/CC-CH Bi2WO6 Fe/CC-CH Ni/CH-FP Fe/CC-CH Ag/RGO
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