Your search keyword '"Huanzhi Lv"' showing total 2 results

1. Engineered K-doped ZnO/borneol based hydrogel composite material for led-based photocatalytic degradation of methylene blue and evaluation of antimicrobial activity

Author

Weiyi Zhang, Dandan Zhang, Huanzhi Lv, Zhenjie Zhou, Lingnan Wang, Shibing Xie, and Zexiang Zheng

Subjects

borneol, hydrogel, ZnO, photocatalytic degradation, antimicrobial activity, Materials of engineering and construction. Mechanics of materials, TA401-492, Chemical technology, TP1-1185

Abstract

The significant improvement of decolorization and disinfection technologies has been a hotspot in wastewater reutilization. In this study, we realized a novel construction of K-doped nano-ZnO and borneol based hydrogel composite material (K-ZnO/B-hydrogel) by low-temperature in situ sol–gel growth. The techniques such as fourier transform infrared (FTIR), X-ray diffraction (XRD), x-ray photoelectron spectroscopy (XPS), scanning electron microscope (SEM) and X-ray energy dispersive spectroscopy (EDS) were applied to recognize the synthesized hydrogel. The results revealed that K-doped ZnO nanoparticles had been uniformly decorated onto the B-hydrogel. Ultraviolet-visible (UV–vis) absorption spectra showed that impurity doping of potassium element into ZnO could reduce the band gap, improving the visible light absorption efficiency. Under LED illumination, the photodegrading rate of K-ZnO/B-hydrogel was approximately 2.3 times greater than that of K-ZnO/B-hydrogel on methylene blue (MB) removal. Remarkably, aside from CO _2 and H _2 O, no by-products were generated during the photodegradation process. In addition, the antimicrobial activities against Escherichia coli ( E. coli ) and Staphylococcus aureus ( S. aureus ) of K-ZnO/B-hydrogel achieved up to 99.9%, which were at least 1.5 times higher than K-ZnO/B-hydrogel. This composite will push ahead with a closed-loop wastewater treatment system for dye and pathogenic microorganism disposal, which combines the excellent adsorption ability of hydrogel and the outstanding photocatalytic ability of ZnO nanoparticles with easy sample handling and separation, and help to eliminate secondary pollution.

Published

2024

2. Al-Modified Ti-MOR as a robust catalyst for cyclohexanone ammoximation with enhanced anti-corrosion performance

Author

Peng Wu, Hao Xu, Zhipeng Wan, Huanzhi Lv, Rusi Peng, and Yejun Guan

Subjects

chemistry.chemical_compound, Hydroxylamine, chemistry, Inorganic chemistry, Cyclohexanone oxime, Cyclohexanone, Leaching (metallurgy), Oxime, Decomposition, Catalysis, Hydrothermal circulation

Abstract

The skeleton desilication accompanied by Ti active sites leaching accounts for the dominant chemical deactivation reasons during the clean industrial production of cyclohexanone oxime through titanosilicate-catalyzed liquid-phase ammoximation in the alkali reaction system. In this study, aluminum species were reintroduced into Ti-MOR by hydrothermal post-treatment with aluminum salts to enhance its anti-corrosion performance against alkaline medium and catalytic stability in cyclohexanone ammoximation reaction. The undesired strengthening in hydroxylamine decomposition and oxime hydrolysis derived from the implantation of aluminum into the framework could be eliminated via further Na+-exchange. By means of quenching bridging Si(OH)Al-related acidic sites selectively, the exchanged process then enhanced catalytic activity significantly in both the hydroxylamine formation and ammoximation processes. With aluminum species enriched on the crystal shell, Ti-MOR after aluminated and Na+-exchanged (denoted as Al-Ti-M-Na) showed a more robust performance in the simulated desilication process and a tremendously prolonged ammoximation lifetime of 460 h, which was 2.75 times that of pristine Ti-MOR. The unprecedented duration of Al-Ti-M-Na was mainly ascribed to the protective effect of the Al-rich shell as it served as the guardian crust that defended the Ti active sites against leaching caused by desilication and skeleton destruction.

Published

2021