Your search keyword '"Liu, Bingzhi"' showing total 5 results

1. Carboxymethyl chitosan modification of cobalt-zinc bimetallic MOF for tetracycline hydrochloride removal: Exploration of the enhancement mechanism of the process.

Author

Liu B, Lu H, Zhuang S, Huang H, Zou C, Tang L, Liu J, Zhang L, Liang J, and Zhao C

Subjects

Adsorption, Catalysis, Water Pollutants, Chemical chemistry, Water Pollutants, Chemical isolation & purification, Water Purification methods, Hydrophobic and Hydrophilic Interactions, Peroxides, Chitosan chemistry, Chitosan analogs & derivatives, Cobalt chemistry, Tetracycline chemistry, Metal-Organic Frameworks chemistry, Zinc chemistry

Abstract

This study synthesized a carboxymethyl chitosan-modified bimetallic Co/Zn-ZIF (CZ@CMC) with strong hydrophilicity and adsorption performance via the one-pot method. Tetracycline hydrochloride (TCH) was used as the model contaminant to evaluate the adsorption and peroxymonosulfate (PMS) activation properties of CZ@CMC. Mechanism showed that the adsorption behavior occurred through pore filling, electrostatic attraction, surface complexation, hydrogen bonding, and π-π stacking. In addition, a CZ@CMC/PMS system was constructed, which had excellent catalytic performance. The hydrophilicity and selective adsorption properties of CMC conferred a greatly accelerated CZ@CMC in catalyzing the PMS process with k obs of 0.095 min -1 , in which OH, 1 O 2 , SO 4 - , O 2 - , and Co(III) were the main ROS which quenching tests, EPR, and chemical probe experiments verified. In addition, the degradation pathways of TCH were obtained utilizing DFT and HPLC-MS and analyzed to show that the system possessed a good detoxification capacity. This work is expected to provide a green, efficient, and stable strategy to enhance the adsorption properties of catalytic materials and subsequently their co-catalytic properties., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published

2024

2. A novel carboxyl-rich chitosan-based polymer and its application for clay flocculation and cationic dye removal.

Author

Liu, Bingzhi, Zheng, Huaili, Wang, Yili, Chen, Xin, Zhao, Chuanliang, An, Yanyan, and Tang, Xiaomin

Subjects

*COLOR removal in water purification, *CHITOSAN, *GRAFT copolymers, *SURFACE structure, *CARBOXYL group, *FLOCCULATION, *BASIC dyes

Abstract

Due to the complexity of contaminants, the effectiveness of traditional flocculants toward water purification is insufficient. To break the limitation, a novel polymer flocculant [chitosan grafted poly (acrylamide-itaconic acid), CS-g-P(AM-IA)] was synthesized via ultraviolet-initiated graft copolymerization reaction. Characterization results revealed that the graft copolymers were successfully synthesized and with rougher surface structure. The solubility of CS-g-P(AM-IA) and chitosan grafted polyacrylamide (CS-g-PAM) were greatly improved and they can dissolve in the wide pH range of 2.0–12.0. CaCl 2 was used as a source of cation bridge to enhance the flocculation of kaolin particles, and its optimum dosage was 150 mg·L −1 . At dosage of 30 mg·L −1 and pH of 5.0, the turbidity removal efficiency of CS-g-P(AM-IA) reached the maximum of 93.8%, whereas those of CS-g-PAM and CS were 96.7% and 76.9%, respectively. The patchwise adsorption of ionic groups embedded in the molecular chain on Ca 2+ -clay complexes took effect to generate flocs with larger particle size. Besides, the decolorization ability of cationic dyes by CS-g-P(AM-IA) was greatly enhanced due to the role of abundant carboxyl groups. In the crystal violet (CV) adsorption experiment, the maximum CV dye removal efficiency for CS-g-P(AM-IA) reached the maximum of 81.6% at dosage of 0.7 mg·mL −1 and pH of 9.0, while those for CS-g-PAM and CS were 51.7% and 36.5%, respectively. [ABSTRACT FROM AUTHOR]

Published

2018

3. Synthesis of a chitosan-based flocculant CS-g-P(AM-IA-AATPAC) and evaluation of its performance on Ni2+ removal: Role of chelating-coordination and flocculation.

Author

Feng, Li, Zhong, Kunyu, Zhou, Wen, Liu, Jiajun, Liu, Bingzhi, Wang, Wanying, and Zheng, Huaili

Subjects

FLOCCULANTS, FLOCCULATION, MOLECULAR weights, FRACTAL dimensions, WATER pollution, WASTEWATER treatment, GLUTARALDEHYDE, DISSOLVED air flotation (Water purification)

Abstract

Ni2+ rich wastewater has caused critical water contamination, a growing issue of environmental pollution as well as serious threat to aquatic organisms and human health. It is of great significance and urgent to develop a novel and efficient wastewater treatment technology for Ni2+ removal. The efficient removal of Ni2+ by flocculation has always become a hot and focus topic. In this study, a novel chitosan (CS) graft modified flocculants CS-g-P(AM-IA-AATPAC), namely CS-g-PAAI, is prepared by microwave initiation and polymerization, and is applied in the removal of Ni2+. The effects of microwave power, microwave irradiation time, initiator concentration and pH on the CS graft polymerization efficiency and flocculant molecular weight were investigated and optimized, so as to further understand the rules of microwave initiation and CS-g-PAAI graft and polymerization. Various characterization methods indicated the successful grafting and synthesis of CS-g-PAAI. Meanwhile, the structural characteristic results manifested that CS-g-PAAI possessed a good thermal stability, a coarse and porous apparent morphology, and its chemistry and crystal structure was evidently changed and affected after graft polymerization. Compared with CS, PAA and CS-g-PAA, the removal efficiency of Ni2+ by CS-g-PAAI is more exceedingly favorable and desirable. The flocculation effect of Ni2+ by CS-g-PAAI is as high as 86.3% at the optimal condition of pH = 9, flocculant dosage = 4 mg/L, the stirring speed = 400 rpm, and flocculation time = 30 min. Meanwhile, the generated Ni2+ floc size (d 50) and fractal dimension (D f) can reach a high value (d 50 = 339.3 µm, D f = 1.98), which accelerates the sedimentation and separation of the formed Ni2+ flocs. CS-g-PAAI shows excellent flocculation and coordination ability by its powerful coordination groups to strengthen the adsorption and chelating of Ni2+ ions and generate colloidal particles for subsequent flocculation. Then, efficient flocculation was carried out and proceeded through the bridging effect, the concomitant sweeping and netting action. [Display omitted] • CS-g-PAAI with both flocculation and coordination chelating effect was successfully synthesized. • There is a significant synergistic effect between flocculation and coordination chelating. • The introduction of IA can significantly improve the flocculation and removal effect of Ni2+. • 4. The Ni2+ floc particle size and fractal dimension conditioned by CS-g-PAAI are large and desirable. [ABSTRACT FROM AUTHOR]

Published

2023

4. Octopus tentacle-like molecular chains in magnetic flocculant enhances the removal of Cu(II) and malachite green in water.

Author

Liu, Bingzhi, Lu, Haitao, Wu, Shenyu, Wang, Zizeng, Feng, Li, and Zheng, Huaili

Subjects

*MALACHITE green, *CARBON content of water, *CHEMICAL properties, *WATER purification, *OCTOPUSES

Abstract

[Display omitted] • A recyclable flocculant with strong adsorption configuration was prepared simply. • Flocculant can remove Cu(II) and malachite green efficiently and synchronously. • Adsorption by functional groups and sweep flocculation were the mechanism. • Flocculant was easily regenerated and separated. • Flocculant can remove multiple contaminants in single-stage water treatment. Conventional flocculants are difficult to effectively remove dissolved ions and organic matter from water. This work aims to develop an environmentally friendly and renewable core–shell type flocculant (MCHS-g-P(AM-IA)) with octopus tentacle-like strong adsorption structure. The organic shell hydrolyses into molecular chains like octopus tentacles and adsorb dissolved ions/organic macromolecules through suckers-like functional groups, while the magnetic core acts as the growth center of flocs. Configuration and physical/chemical properties of the flocculant were analyzed by a series of characterization methods. Set Cu(II) and malachite green (MG) as models of heavy metal and organic pollutants separately, the removal capacity of MCHS-g-P(AM-IA) for water contaminants was studied in single-contaminant system and binary-contaminant system. The flocculation behavior and mechanism of MCHS-g-P(AM-IA) were deeply investigated by analysis of pH-dependence, background cationic influence and flocculation kinetics and SEM-EDS/XPS analysis of flocs. Furthermore, the flocculation performance in actual water matrix and regeneration tests of MCHS-g-P(AM-IA) were carried out to evaluate the applicable feasibility of flocculants for purification of complex wastewater in single stage water treatment. [ABSTRACT FROM AUTHOR]

Published

2022

5. Chitosan Modified Cationic Polyacrylamide Initiated by UV-H 2 O 2 for Sludge Flocculation and New Insight on the Floc Characteristics Study.

Author

Chen, Jie, Xu, Xiaojun, Nie, Rui, Feng, Li, Li, Xuhao, and Liu, Bingzhi

Subjects

POLYACRYLAMIDE, FLOCCULATION, SLUDGE conditioning, CHITOSAN, MOLECULAR weights, X-ray photoelectron spectroscopy, FRACTAL dimensions

Abstract

In the present study, a novel graft modified flocculant CTS-g-PAMD was synthesized and applied to conduct sludge conditioning and dewatering. CTS-g-PAMD was copolymerized with AM, DMC and chitosan (CTS) under UV-H2O2 initiation. In addition, the effects of single factor experiments on the molecular weight (MW) CTS grafting efficiency (GE) of CTS-g-PAMD were determined and the optimal copolymerization conditions were achieved. The GE of CTS-g-PAMD reached 91.1% and the MW was 4.82 × 106 Da. As revealed from the characterized results of Fourier-transform infrared spectra (FT-IR), 1H/ NMR, X-ray diffraction (XRD), scanning electron microscopic (SEM) and X-ray photoelectron spectroscopy (XPS), the successful synthesis of CTS-g-PAMD was confirmed, which is considered to be conducive to explaining sludge dewatering performance. Under the optimal conditions (pH = 7.0, flocculant dosage = 35 mg/L), the best flocculating performance (FCMC: 73.7%; SRF: 4.7 × 1012 m·kg−1, turbidity: 9.4 NTU) and large and dense sludge flocs (floc size d50 = 379.142 µm, floc fractal dimension Df = 1.58) were formed. The DMC and CTS chain segments exhibiting cationic properties significantly improved the positive charge density and enhanced the electrical patching effect of CTS-g-PAMD. The long molecular chain of CTS-g-PAMD exhibited superior extensibility, which enhanced bridging effect on adsorption. Moreover, the sludge floc after undergoing CTS-g-PAMD conditioning exhibited robust shear resistance and regeneration ability. After the sludge floc was crushed and broken, a large and dense sludge floc was formed, helping significantly reduce the sludge specific resistance (SRF), turbidity and cake moisture content (FCMC) and enhance the sludge dewatering effect. The novel CTS-g-PAMD flocculant shows promising practical applications and high market value. [ABSTRACT FROM AUTHOR]

Published

2020