Your search keyword '"Fang, Shengqiong"' showing total 3 results

1. A Cobalt‐Modified Covalent Triazine‐Based Framework as an Efficient Cocatalyst for Visible‐Light‐Driven Photocatalytic CO2 Reduction.

Author

Bi, Jinhong, Xu, Bin, Sun, Long, Huang, Huimin, Fang, Shengqiong, Li, Liuyi, and Wu, Ling

Subjects

PHOTOREDUCTION, COBALT, CHARGE transfer, CHARGE exchange, TRIAZINES, SOLAR energy, SOLAR technology

Abstract

Photocatalytic CO2 reduction into carbonaceous feedstock chemicals is a promising renewable energy technology to convert solar energy and greenhouse gases into chemical fuels. Here, a covalent triazine‐based framework (CTF) is demonstrated as an efficient cocatalyst to reduce CO2 under visible‐light irradiation. The nitrogen‐rich triazine moieties in CTF contribute to CO2 adsorption, while the periodical pore structure of CTF favors the accommodation of CO2 and electron mediator. Immobilization of cobalt species onto CTF promotes the photocatalytic activity with a 44‐fold enhancement over pristine CTF and the optimal CO production rate of the obtained Co/CTFs was up to 50 μmol g−1 h−1. The results of solid‐state UV‐vis diffuse reflectance spectra (UV‐vis DRS), CO2 adsorption and electrochemical impedance spectroscopy (EIS) illustrated that the increased activity was ascribed to the enhanced CO2 capture capacity, improved absorption of visible‐light and facilitated the transfer of charge from CTF to CO2 molecules. The CTF not only serves as a substrate for active Co species, but also bridges the photosensitizer with cobalt catalytic sites for the efficient transfer of photoexcited electrons. This work highlights the capability and ease of fabricating covalent organic framework‐based photocatalytic systems that are potentially useful for energy‐conversion applications. [ABSTRACT FROM AUTHOR]

Published

2019

2. Highly efficient activation of peroxymonosulfate by Co, S co-doped bamboo biochar for sulfamethoxazole degradation: Insights into the role of S.

Author

Huang, Xiaoyi, Yu, Zhendong, Shi, Yanbiao, Liu, Qingsong, and Fang, Shengqiong

Subjects

STRUCTURE-activity relationships, PEROXYMONOSULFATE, SULFAMETHOXAZOLE, CHARGE exchange, BIOCHAR, DIMETHYL sulfoxide

Abstract

Recently, highly efficient activation of peroxymonosulfate (PMS) by S-doped cobalt-based catalysts are receiving increased attention. The effect of S is worth exploring since it has a great influence on PMS activation performance. In this work, dimethyl sulfoxide was adopted as an S source and loaded on bamboo biochar (BB) with Co to form CoS/BBC, which served as an efficient catalyst for PMS activation to degrade sulfamethoxazole (SMX). The experiment results showed that CoS/BBC exhibits an excellent catalytic activity and the SMX (20 mg/L) can be completely degraded under the attack of species of · OH, SO 4 - · , 1O 2 and electron transfer. The SMX degradation conformed to pseudo first-order kinetics with rate constant reaching 0.442 min−1 in 10 min under the optimal conditions (a catalyst dose of 0.02 g/L, a PMS dose of 0.3 g/L and an initial pH = 7.0). The electrochemical experiments and density functional theory (DFT) calculation revealed that the introduction of S can accelerate electron transfer and promote the decomposition of PMS while facilitating Co(III)/Co(II) redox cycling. Furthermore, liquid chromatograph-mass spectrometer (LC-MS) and ecological structure activity relationships (ECOSAR) proved that the degradation process of SMX in CoS/BBC/PMS system has low ecotoxicity and is harmless to the environment. This work provides a new strategy for enhancing electron transfer by S-doped metal materials and the synthesis of efficient catalysts for SMX removal. [Display omitted] • CoS/BBC/PMS system presented > 99% removal efficiency within 10 min. • S accelerated electron transfer and promoted Co(III)/Co(II) redox cycling. • Effects of anions and dissolved organic matters on PMS activation were studied. • SMX degradation pathways were proposed and verified by LC-MS and DFT. • Sulfamethoxazole degradation in this system was a toxicity-attenuation process. [ABSTRACT FROM AUTHOR]

Published

2022

3. The CoO-doped carbon nanotubes enhance electronic performance and effectively activate persulfate for the degradation of sulfafurazole.

Author

Liu, Qingsong, Zhou, Bin, Zheng, Caihong, Wang, Dong, Ge, Yao, and Fang, Shengqiong

Subjects

*CARBON nanotubes, *ENVIRONMENTAL risk assessment, *ELECTRON transport, *CHARGE exchange, *CATALYTIC activity, *DENSITY functional theory, *FENTON'S reagent

Abstract

In recent studies, carbon nanotube (CNTs) materials and their composites have demonstrated remarkable catalytic activity in the activation of persulfate (PS), facilitating the efficient degradation of organic pollutants. In this study, a novel Co loaded carbon nanotubes (CoO@CNT) catalyst was prepared to promote PDS activation for the degradation of sulfafurazole (SIZ). Experimental results, the CNT as a carrier effectively reduces the leaching of cobalt ions and improves the electron transport capacity，whereas the introduced Co effectively activates the PDS, promoting the generation of highly reactive radicals to degrade SIZ. Under optimized conditions (a catalyst dose of 0.2 g/L, a PDS dose of 1 g/L and an initial pH = 9.0), the obtained CoO@CNT demonstrated favorable Fenton-like performance, reaching a degradation efficiency of 95.55% within 30 min. Furthermore, density functional theory (DFT) calculations demonstrate that the introduction of cobalt (Co) accelerates electron transfer, promoting the decomposition of PDS while facilitating the Co2+/Co3+ redox cycling. We further employed the environmental chemistry and risk assessment system (ECOSAR) to evaluate the ecological toxicity of intermediate products, revealing a significant reduction in ecological toxicity associated with this degradation process, thereby confirming its environmental harmlessness. Through batch experiments and studies, we gained a comprehensive understanding of the mechanism and influencing factors of CoO@CNT in the role of SIZ degradation, and provided robust support for evaluating the ecological toxicity of degradation products. This study provides a significant strategy for the development of efficient catalysts incorporating Co for the environmentally friendly degradation of organic pollutants. • The introduced CoO effectively activate the PDS, promoting the generation of highly reactive radicals to degrade SIZ. • DFT calculations demonstrate that the introduction of Co accelerates electron transfer, promoting the decomposition of PDS. • We also assessed the ecological toxicity of intermediate products using the ECOSAR. [ABSTRACT FROM AUTHOR]

Published

2024