Your search keyword '"Liu, Riri"' showing total 4 results

1. Electrophoretic nuclei assembly of MOFs in polyamide membranes for enhanced nanofiltration.

Author

Li, Jian, Liu, Riri, Zhu, Junyong, Li, Xin, Yuan, Shushan, Tian, Miaomiao, Wang, Jing, Luis, Patricia, der Bruggen, Bart Van, and Lin, Jiuyang

Subjects

*POLYAMIDE membranes, *NANOFILTRATION, *ELECTROPHORETIC deposition, *MEMBRANE separation, *SURFACE charges, *COMPOSITE membranes (Chemistry), *POLYAMIDES, *WATER filtration

Abstract

Thin film nanocomposite (TFN) polyamide (PA) membranes has drawn increasing attention due to the improved physicochemical properties of the top layer for versatile separation performance. However, the commonly used fabrication approach, lacking a controllable loading of nanofillers, leads to a random and insufficient distribution of nanofillers into the PA layer and generates interfacial defects that deteriorate the membrane performance. Herein, a rational strategy for incorporating metal-organic frameworks (i.e., ZIF-8) into the PA layer via electrophoretic deposition (EPD) was proposed. Driven by an external direct current field, the ZIF-8 nanoparticles were uniformly assembled onto a porous ultrafiltration (UF) substrate for fabrication of high-performance TFN nanofiltration membranes by vacuum-assisted interfacial polymerization (IP). The resultant TFN nanofiltration membrane yielded an enhanced water permeability of 22.4 ± 1.2 L·m−2·h−1·bar−1, due to incorporation of ZIF-8 nanoparticles which created extra nano-channels for fast water permeation. Additionally, such an EPD process effectively tailored the membrane surface properties (e.g., zeta potential) and conferred a considerably high rejection for Na 2 SO 4 (96.9 ± 0.7%) but a low rejection for NaCl (18.9 ± 2.5%), demonstrating an excellent selectivity between SO 4 2− and Cl− ions. This study highlights the impressive efficacy of the EPD process in precisely anchoring nanomaterials to design high-performance TFN nanofiltration membranes for target separations. [Display omitted] • Electrophoretic deposition (EPD) is used to assemble ZIF-8 into polyamide membrane. • Uniform and sufficient assembly of ZIF-8 is achieved by precisely controlling the ageing and EPD times. • Uniform ZIF-8 assembly into the polyamide layer creates extra nano-channels for enhanced flux. • ZIF-8 assembly by EPD tailors the surface charge of TFN membranes, yielding an enhanced selectivity between SO 4 2− and Cl−. [ABSTRACT FROM AUTHOR]

Published

2021

2. Elevated nanofiltration performance via mussel-inspired co-deposition for sustainable resource extraction from landfill leachate concentrate.

Author

Ye, Wenyuan, Liu, Riri, Lin, Fang, Ye, Kunfeng, Lin, Jiuyang, Zhao, Shuaifei, and Van der Bruggen, Bart

Subjects

*WATER filtration, *NANOFILTRATION, *LEACHATE, *LANDFILLS, *WASTE recycling, *HUMUS, *ORGANIC fertilizers

Abstract

• Mussel-inspired co-deposition was used to effectively tailor the surface property of NF membrane. • The modified NF membrane yielded a molecular weight cut-off of 305 Da after 90-min co-deposition. • The modified NF membrane showed enhanced fractionation of humic substances (HS) and salts. • NF-based diafiltration enriched and purified the HS from landfill leachate concentrate for sustainability. During the disposal of highly saline wastewaters, i.e., landfill leachate concentrate, a conceptual and paradigmatic transformation from contaminant elimination to sustainable resource extraction urges for novel selective membranes. Mussel-inspired modification through dopamine self-polymerization can be a competitive alternative to tailor the membrane surface properties for enhanced permselectivity to target compounds. Herein, co-deposition of polydopamine-polyethylenimine (PEI) complex onto loose nanofiltration (NF) membranes was conducted using persulfate as trigger, which resulted in a significant alteration in membrane surface properties. Particularly, the pore size of bio-inspired NF membranes decreased, along with a reduction in molecular weight cut-off (MWCO) from 640 to 298 Da after 120-min bio-inspired coating, which yielded an enhancement in rejection of humic substances from 95.1% to 98.9% in filtration of landfill leachate concentrate. Furthermore, the charge of membrane surface was tailored to be more positive due to incorporation of positively-charged PEI, which markedly undermined the electrostatic repulsion force for enhanced salt permeation. These bio-inspired NF membranes showed a superior selectivity between humic substances and salts for their potential fractionation from the landfill leachate concentrate. Through an integrated NF-based diafiltration procedure, the concentration of humic substances was remarkably enriched from 1779.4 to 17247.1 mg·L−1 with 96.0% recovery. Additionally, 99.5% desalination efficiency was achieved, resulting in a high purity (i.e., 98.3%) for humic substances as potential organic fertilizer application. These findings suggest that the bio-inspired co-deposition is an effective strategy to tailor the surface properties of NF membranes for efficient fractionation of humic substances and salts, in view of sustainable resource recovery from the landfill leachate concentrate. [ABSTRACT FROM AUTHOR]

Published

2020

3. Choline chloride modification of nanofiltration membranes for improving heavy metal ions separation in wastewater.

Author

Li, Junwei, Song, Yihao, Xu, Daliang, Zhang, Xi, Du, Jiale, Liu, Riri, Zhao, Rui, Chen, Qin, Volodine, Alexander, Dewil, Raf, Gao, Qieyuan, and Van der Bruggen, Bart

Subjects

*CHOLINE chloride, *CHOLINE, *HEAVY metals, *METAL ions, *NANOFILTRATION, *DENSITY functionals, *ELECTRODIALYSIS, *WATER filtration

Abstract

The growing concern over heavy metal ion contamination in industrial wastewater, posing a significant threat to global public health, has led to a heightened interest in devising efficient removal methods. Nanofiltration, while promising, faces a substantial challenge in simultaneously achieving a high rejection of heavy metal cations and maintaining an elevated water permeance. In response, this study utilizes a simple approach by employing choline chloride with a quaternary ammonium group to modify the surface of PEI-TMC membrane, leading to the design of a high-performance PEI-TMC-CC membrane. The choline chloride modification optimized the surface morphology, hydrophilicity, roughness, and combined the Donnan exclusion effect as well as sieving effect, enabling the PEI-TMC-CC membrane to achieve an exceptional rejection of heavy metal ions while retaining a great water permeance. An impressive water permeance 10.0 L m−2 h−1 bar−1 was performed by the PEI-TMC-CC membrane, nearly three times that of traditional PEI-TMC membranes. Concurrently, the PEI-TMC-CC membrane demonstrated an impressive rejection of heavy metals Cd2+, Pb2+, Ni2+, Zn2+, and Cu2+, reaching rejections of 98.3 %, 95.9 %, 98.1 %, 98.5 % and 99.1 %, respectively. Moreover, density functional theory (DFT) calculations confirmed the improved hydrophilicity of choline chloride molecules, aligning with experimental results. The modification of traditional nanofiltration membranes using cost-effective, hydrophilic, positively charged chemicals not only leads to significant performance improvements but also holds the potential to advance the development of positively charged nanofiltration membranes tailored for the removing of heavy metals cations from wastewater. This approach demonstrates promising prospects for industrial applications and further development. [Display omitted] • The affordability and non-toxic choline chloride was employed to modify the surface of PEI-TMC membrane. • The hydrophilicity of choline chloride were demonsitrated by Density Functional Theory method. • The choline chloride improve the membrane permeance while retaining the great rejection of heavy metal cations. [ABSTRACT FROM AUTHOR]

Published

2024

4. Sustainable management of landfill leachate concentrate via nanofiltration enhanced by one-step rapid assembly of metal-organic coordination complexes.

Author

Lin, Jiuyang, Chen, Qin, Liu, Riri, Ye, Wenyuan, Luis, Patricia, Van der Bruggen, Bart, and Zhao, Shuaifei

Subjects

*LANDFILL management, *NANOFILTRATION, *HUMUS, *LEACHATE, *LIQUID fertilizers, *SURFACE coatings, *POLYETHERSULFONE

Abstract

• Metal-organic coordination complex coating effectively tailors surface property of nanofiltration membrane. • The nanofiltration membrane yields a molecular weight cutoff of 297 Da after 15-s coating. • The coated nanofiltration membrane shows impressive fractionation of humic substances and salts. • Nanofiltration-diafiltration can enrich and purify humic substances from landfill leachate concentrate. Sustainable treatment of the highly saline landfill leachate concentrate for application as green fertilizer calls for effective fractionation of the existing humic substances and inorganic salts; advanced selective nanofiltration membranes are proposed for this. One-step, rapid assembly of a tannic acid-Fe3+ coordination complex is a promising strategy to endow the membranes with an enhanced nanofiltration performance. In this study, a robust and homogeneous tannic acid-Fe3+ coordination complex layer was effectively coated onto the surface of a loose nanofiltration substrate in an extremely short time (15 s). After the coating of the tannic acid-Fe3+ coordination complex layer, the nanofiltration membrane showed a significantly reduced molecule weight cutoff (i.e., reduction from 601 to 279 Da) and thus enhanced selectivity towards humic substances. Specifically, the rejection to humic substances of the coated nanofiltration membrane increased from 95.31±0.54% to 99.32±0.18% with negligible rise in salt rejection, demonstrating an enhanced fractionation efficacy for humic substances and salts. Assisted by a diafiltration operation with the coated nanofiltration membrane, humic substances in the landfill leachate concentrate were effectively purified and extracted with 96.60% recovery. Particularly, the humic substances were linearly enriched by ca. 7.8 folds (i.e., from 1837 to 13970 mg·L−1) with a purity of 98.91% for potential application as liquid fertilizer. The one-step rapid tannic acid-Fe3+ coordination complex coating exhibits an impressive efficacy to engineer advanced nanofiltration membranes that could be applied at a large scale for sustainable resource extraction from landfill leachate concentrate. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2021