30 results on '"Wang Rong"'
Search Results
2. High‐Precision and High‐Flux Separation by Rationally Designing the Nanochannels and Surface Nanostructure of Polyamide Nanofiltration Membranes.
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Zheng, Han, Mou, Zihao, Lim, Yu Jie, Srikanth, Narasimalu, Zhang, Wang, Guo, Sheng, Wang, Rong, and Zhou, Kun
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POLYAMIDE membranes ,MARITIME shipping ,AMMONIUM ions ,POLYAMIDES ,MEMBRANE separation ,ACTIVATION energy ,COMPOSITE membranes (Chemistry) ,REVERSE osmosis - Abstract
High‐precision separation with increased water permeability is critical for efficient membrane‐based water treatment processes. To achieve high selectivity toward different targeted species while allowing rapid water transportation, the structure of the membrane polyamide selective layer requires delicate regulation. Herein, an effective approach to systematically expand the pore size of polyamide layers by incorporating ammonium ion‐modified carbon dots (CDs) into the polyamide network is developed. The ammonium ions with different alkyl chain lengths attached to the CDs create nanochannels of different sizes in the network to lower the energy barrier for water transportation while maintaining high selectivity to targeted species. When the alkyl chain length of the ammonium ions reaches eight carbon atoms (i.e., C8 ions), the amphiphilic C8‐CDs induce the formation of the ridged nanostructure on the membrane surface and hence the increased membrane filtration area. The resultant thin‐film nanocomposite (TFN) membrane, denoted as the TFN‐C8‐CDs membrane, demonstrates a higher Na2SO4 rejection of 98.9% and NaCl/Na2SO4 selectivity of 83.1 than the pristine polyamide membrane, together with a tripled pure water permeability of 29.0 L m−2 h−1 bar−1. Herein, a viable approach for ingeniously designing the nanochannels and surface nanostructure of polyamide membranes for more efficient filtration processes is provided. [ABSTRACT FROM AUTHOR]
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- 2022
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3. Response surface modeling and optimization of electrodialysis for reclamation of RO concentrates in coal-fired power plants.
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Xu, Yuting, Sun, Yongchao, Ma, Zhun, Wang, Rong, Wang, Xiuju, Wang, Jian, Wang, Liguo, Gao, Xueli, and Gao, Jun
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COAL-fired power plants ,REVERSE osmosis ,REGRESSION analysis ,ANALYSIS of variance ,ENERGY consumption - Abstract
Response surface methodology was employed to model and optimize the electrodialysis process for Reverse osmosis concentrate (ROC) reclamation in coal-fired power plants. Predictive models were developed for simulation of different input parameters and responses of ED process. The model for responses was statistically verified by analysis of variance which generated a high coefficient of determination value. Moreover, regression analysis showed a good repeatability and agreement of the experimental data to a quadratic model. The optimum operating parameters were found to be 5.9 V of operational voltage, 1.19 m/s of flow rate and 74 min of time. And the corresponding energy consumption and desalination rate were 0.11 Wh/L and 75.3%, respectively. [ABSTRACT FROM AUTHOR]
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- 2020
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4. High-performance reverse osmosis membranes fabricated on highly porous microstructured supports.
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Lee, Jaewoo, Wang, Rong, and Bae, Tae-Hyun
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REVERSE osmosis (Water purification) , *FABRICATION (Manufacturing) , *POROUS materials , *THERMODYNAMICS , *DESOLVATION - Abstract
Increasing the surface porosity of a support membrane has been proposed as an effective way to improve the water permeability of thin-film composite (TFC) reverse osmosis (RO) membranes by reducing the diffusion pathway in the active layer. In this work, we prepared a highly porous microstructured (HPμS) support membrane with a suitable mechanical strength to enhance the water permeability of an RO membrane. The HPμS support membrane was prepared by increasing the thermodynamic instability of a 10 wt% polymer solution and thereby facilitating rapid desolvation. The rapid desolvation formed the narrow and regularly arranged pore structure in the sublayer, and we proposed the mechanism for the sublayer structure formation based on analyses of the thermodynamic properties of such a binary system. Owing to the narrow and regular structure, the HPμS support membranes showed the exceptional mechanical strength, which was comparable to the strength of support membranes used for conventional RO membranes. Also, the HPμS support membranes successfully endowed an in-house RO membrane with the performance (water permeability of 4.68 L m −2 h −1 bar −1 and NaCl rejection of 98.3%) surpassing commercial RO membranes and thin-film nanocomposite membranes recently reported in the literature. [ABSTRACT FROM AUTHOR]
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- 2018
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5. Aquaporin-based biomimetic reverse osmosis membranes: Stability and long term performance.
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Qi, Saren, Wang, Rong, Chaitra, Gopala Krishna Moorthi, Torres, Jaume, Hu, Xiao, and Fane, Anthony Gordon
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AQUAPORINS , *BIOMIMETIC chemicals , *REVERSE osmosis , *POLYMERIZATION , *ETHYLENEDIAMINETETRAACETIC acid - Abstract
This study investigated the stability of the aquaporin-based biomimetic (ABM) membrane and its long-term reverse osmosis (RO) performance. A series of experiments showed that the ABM membranes exhibited good chemical stability after soaking in three commonly used chemical cleaning agents, namely ethylenediamine tetraacetic acid (EDTA), sodium hydroxide (NaOH) and citric acid, respectively. In addition, it was found that both water permeability (flux per unit applied pressure) and solute rejection of ABM membranes are sensitive to the temperature and applied pressure. In the long-term RO performance evaluation, a real RO feed water from water reclamation process was used as feed; this is the first reported application of real RO feed water to ABM membranes. The membranes were periodically cleaned and the recovery of water permeability of the ABM membranes was found to be greater than 90%. The quality of the water permeate exceeded the World Health Organisation standard for drinking water. Compared with a commercial RO membrane, the ABM membrane only needed half of the applied pressure to achieve the same water flux, suggesting the advantage and potential of ABM membranes to reduce energy consumption in practical applications. [ABSTRACT FROM AUTHOR]
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- 2016
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6. High-temperature reverse osmosis and molecular separation with robust polyamide-ceramic membranes.
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Chong, Jeng Yi, Zhao, Yali, and Wang, Rong
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MOLECULAR weights , *SURFACE charges , *SUBSTRATES (Materials science) , *THERMAL stability , *HIGH temperatures , *REVERSE osmosis , *COMPOSITE membranes (Chemistry) - Abstract
[Display omitted] • RO-type polyamide (PA) thin-film was synthesized on ceramic tubular substrates. • The PA-ceramic membranes showed excellent performance and stability in HT-RO. • The MWCO increased at HT and surface charge was critical for salt rejection. • PA thin-films are stable at < 75 °C but thermal hydrolysis was observed at 80 °C. • The robustness of the substrates could enhance the membrane stability in HT-RO. Polyamide thin-film composite (TFC) membranes are widely used for reverse osmosis (RO), but most commercial RO membranes have a limited operating temperature of <45 °C. This has constrained the broader applications of RO in industries, where process and water feeds with high temperature >50 °C are common. In this study, robust polyamide-ceramic TFC membranes were developed for high-temperature RO (HT-RO). RO-type polyamide thin-film was successfully synthesized on the inner surface of ceramic tubular membranes via interfacial polymerization. The polyamide-ceramic membranes exhibited excellent thermal stability, maintaining high NaCl rejection (>98 %) and steady water permeability (∼5 LMH/bar) during HT-RO at 70 °C. The molecular weight cut-off (MWCO) of the membranes increased slightly from 90 to 140 Da at 70 °C, and the surface charge played an important role in maintaining the high salt rejection. Long-term stability tests showed that polyamide thin-films may undergo thermal hydrolysis at 80 °C. It was also found that polymeric substrates of flat-sheet RO membranes may experience serious compaction at high temperature, which could subsequently affect the performance and stability of the polyamide layer. The ceramic substrates provide strong support at high temperature, and the highly stable polyamide-ceramic membranes demonstrated huge potential for RO applications under more challenging conditions. [ABSTRACT FROM AUTHOR]
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- 2024
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7. Unique roles of aminosilane in developing anti-fouling thin film composite (TFC) membranes for pressure retarded osmosis (PRO).
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Zhang, Lizhi, She, Qianhong, Wang, Rong, Wongchitphimon, Sunee, Chen, Yunfeng, and Fane, Anthony G.
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SILANE compounds , *BIOCIDES , *THIN films , *COMPOSITE materials , *REVERSE osmosis - Abstract
Pressure retarded osmosis (PRO) has been identified as a promising technology to harvest the salinity gradient energy. For practical applications of PRO process, membrane fouling is a challenging issue as it leads to severe decline of PRO performance in terms of water flux and power density. It is imperative to develop anti-fouling membranes for PRO process. The current study demonstrated the unique roles and the great potential of aminosilane in developing anti-fouling thin film composite (TFC) PRO membranes. Experimental results revealed that aminosilane as a grafting agent can modify both the support layer (interior) and the selective layer of PRO membranes with remarkably enhanced hydrophilicity via a very simple grafting procedure. In the grafting, aminosilane was able to minimize the pore-blocking issue with almost no increase in the membrane structural parameter ( S ). Meanwhile, the membrane mechanical strength was well maintained with the grafting due to the capability of aminosilane as a cross-linker. With enhanced hydrophilicity, it was interestingly found that the water permeability ( A ) was doubled, while the salt rejection was maintained nearly unchanged. The combination of these effects brought in remarkably enhanced water flux, power density and anti-fouling property to the resultant membrane. [ABSTRACT FROM AUTHOR]
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- 2016
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8. Liposome-integrated seawater reverse osmosis membrane prepared via facile spray-assisted interfacial polymerization.
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Lai, Gwo Sung, Zhao, Yali, and Wang, Rong
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REVERSE osmosis , *LIPOSOMES , *SEAWATER , *POLYMERIZATION , *THIN films , *PERMEABILITY , *POLYAMIDES - Abstract
In this work, we demonstrated the effectiveness of using spray-assisted interfacial polymerization (IP) technique in fabricating liposome-integrated thin film nanocomposite (TFN) membranes for seawater reverse osmosis (SWRO). The liposome loading within the selective polyamide (PA) layer of the TFN membrane can be precisely controlled by manipulating spraying conditions to eliminate the wastage of precious additives compared to the conventional blending method. Spraying the liposomes after applying the aqueous phase of M -phenylenediamine (MPD) could prevent the loss and disruption of liposome distribution over the substrate layer. Upon incorporating 4 mg/m2 of liposomes, the best-performing S4-a membrane is able to achieve 27% higher water permeability than the liposome-free membrane, demonstrating a permeability of 3.24 L/m2·h·bar along with 99.3% NaCl rejection for seawater desalination. Characterization showed that dynamic liposomes had affected the IP process by creating a larger miscible reaction zone for IP, which led to the formation of a rougher PA surface with more nanovoids in the ultra-thin selective layer, thus, contributing to higher effective surface area and less hydraulic resistance for improving water permeability. An additional PVA layer was coated atop the liposome-integrated membrane to effectively improve the membrane stability and fouling resistance, leading to a comparable level of salt rejection with the state-of-the-art commercial membranes in treating real seawater, while water permeability was enhanced by 26–185%. This work presents a readily scalable spray-assisted IP technique to fabricate liposome-integrated SWRO membrane for seawater desalination. [Display omitted] • DOPC liposomes were integrated into PA layer via spray-assisted IP approach. • Spraying DOPC liposomes after aqueous phase of IP ensured precise control of liposome amount. • DOPC liposomes resulted in forming a rougher PA surface with larger nanovoids. • The best membrane exhibited 3.24 L/m2·h·bar permeability with 99.3% NaCl rejection. • PVA coated liposome-integrated membrane demonstrated excellent stability and fouling resistance. [ABSTRACT FROM AUTHOR]
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- 2022
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9. Demystifying the compaction effects of TFC polyamide membranes in the desalination of hypersaline brine via high-pressure RO.
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Lim, Yu Jie, Nadzri, Naeem, Lai, Gwo Sung, and Wang, Rong
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SALINE water conversion , *COMPOSITE membranes (Chemistry) , *POLYAMIDE membranes , *REVERSE osmosis , *COMPACTING , *YOUNG'S modulus , *FEED additives - Abstract
High-pressure reverse osmosis (HPRO) holds promise as a technology for the energy-efficient desalination of hypersaline brine (≥70 g/L total dissolved solids). In this work, we examined the effects of membrane compaction for four types of thin-film composite (TFC) RO membranes from DuPont Water Solutions (XLE, BW30, SW30HR, and XUS180808) using a crossflow filtration setup. The membranes were tested at a maximum applied pressure (ΔP) of 200 bar using a seawater desalination brine feed solution (70 g/L NaCl) to simulate conditions encountered in HPRO processes. Post-compaction membrane characterization revealed the densification of the support and selective layers of the TFC membranes (42–61% decrease in thicknesses and 15–22% reduction in polyamide heights, respectively) with respect to their pristine analogues. We also performed a mechanical strength analysis of the support layers that revealed the inverse relationship between the Young's modulus and magnitude of support layer compression. Our results suggest that support layers with a tensile strength ≥7 MPa and a Young's modulus ≥130 MPa are necessary to fabricate mechanically robust TFC membranes for HPRO application. In terms of desalination performance, the least compact-resistant membrane, XLE, displayed a drastic drop in water permeability and salt rejection from 1.63 L m−2 h−1 bar−1 and 97.5% in seawater RO test (ΔP: 55 bar, 35 g/L NaCl feed solution) to 0.39 L m−2 h−1 bar−1 and 95.0% in HPRO test (ΔP: 200 bar, 70 g/L NaCl feed solution). On the other hand, the most compact-resistant membrane, XUS180808, showed the least decline from 0.60 L m−2 h−1 bar−1 and 99.4% in seawater RO test to 0.35 L m−2 h−1 bar−1 and 99.2% in HPRO test. Overall, all four membranes showed irreversible decline in performance after HPRO tests whereby they could not regain their original permeability values at lower pressures (<200 bar). [Display omitted] • TFC membranes were tested in HPRO for brine desalination (ΔP: 200 bar; feed: 70 g/L NaCl). • Best-performing membrane showed a permeability of 0.35 L m−2 h−1 bar−1 (99.2 % rejection). • Compacted membranes displayed a densified support layer (42–61 % decrease in thickness). • Support layers with tensile strength ≥7 MPa and modulus ≥130 MPa are suitable for HPRO. • Nanovoids were preserved in the compacted polyamide layers (∼20 % decrease in height). [ABSTRACT FROM AUTHOR]
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- 2024
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10. Thin film nanocomposite hollow fiber membranes incorporated with surface functionalized HKUST-1 for highly-efficient reverses osmosis desalination process.
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Lin, Yuqing, Chen, Yunfeng, and Wang, Rong
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POLYETHERSULFONE , *REVERSE osmosis , *HOLLOW fibers , *THIN films , *SALINE water conversion , *BRACKISH waters , *HUMIC acid - Abstract
A new class of thin film nanocomposite (TFN) hollow fiber (HF) membrane of polydopamine (PDA) modified HKUST-1 (mHKUST-1) incorporated in polyamide (PA) matrix supported by polyethersulfone (PES) substrate was constructed via interfacial polymerization method for brackish water desalination in low-pressure reverse osmosis (RO) process. The PDA modification facilitated the HKUST-1 even dispersion, thus resulting in better compatibility between the inorganic nanofillers and the organic matrix. The impact of HKUST-1 loadings on the overall performances of the resultant HKUST-1@PA/PES membranes was investigated. Introducing the mHKUST-1 nanofillers not only enhanced surface hydrophilicity and negative surface charges for the selective layer, which improved membrane's fouling resistance to humic acid (HA), but also led to nearly doubled water permeance when comparing with the pristine PA membrane (increasing from 3.51 to 6.94 Lm−2h-1bar−1), without obvious salt rejection deterioration (~98.2% at 2 bar and 97.4% rejections at 4 bar for 500/2000 ppm NaCl solutions, respectively). The integrity of the HKUST-1@PA/PES membrane was examined and verified after 30-days operation. Overall, the results achieved in this work demonstrate promising potential of the metal organic framework (MOF)-based TFN membranes used for desalination in low-pressure RO process. To sum up, this work has exhibited a facile method to incorporate the metal organic framework (MOF) into the PA layer, and the resultant MOF-based TFN membrane indicates its great potential for desalination in low-pressure RO process. • A thin film nanocomposite hollow fiber membrane was constructed via interfacial polymerization. • Polydopamine (PDA) modified HKUST-1 was incorporated in polyamide matrix supported by polyethersulfone substrate. • The PDA modification facilitated the HKUST-1 even dispersion in PA matrix, without the formation of defects. • A water permeability of 6.94 Lm−2h-1bar−1 and 97.4% rejections at 4 bar for 2000 ppm NaCl solution were achieved. • The long-term stability test verified the good integrity of the HKUST-1@PA/PES membranes after 30-days operation. [ABSTRACT FROM AUTHOR]
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- 2019
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11. Fabrication of aquaporin-based biomimetic membrane for seawater desalination.
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Li, Ye, Qi, Saren, Tian, Miao, Widjajanti, Wentalia, and Wang, Rong
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SALINE water conversion , *SEAWATER , *COMPOSITE membranes (Chemistry) , *REVERSE osmosis , *THIN films - Abstract
This study focuses on enhancing the mechanical strength of aquaporin (AQP)-based biomimetic membranes for seawater desalination. AQP incorporated vesicles were embedded into the selective layer of an optimized thin film composite (TFC) membrane. The resultant membrane, denoted as ASW, exhibited a stable water flux around 20 L·m−2·h−1 and 99% NaCl rejection at a constant pressure of 55 bar using 32,000 mg·L−1 NaCl solution as feed in reverse osmosis (RO) measurement. The robustness of the ASW membranes were evaluated. The water flux of ASW membrane was almost 100% enhanced compared with that of AQP-free control TFC membranes. The filtration performance of the ASW membrane was further evaluated by a seven-day desalination test using a real seawater secondary effluent collected from a desalination plant in Singapore as feed. To our best knowledge, our study is the first report on the AQP-incorporated RO membrane applied for seawater desalination. A commercial SW30HR membrane was tested in parallel for comparison. The robust ASW membrane exhibited a nearly 80% higher water flux in comparison to the SW30HR membrane with a comparable overall solute rejection, suggesting the advantage and feasibility of Aquaporin based biomimetic membranes for seawater desalination. • The mechanical strength of aquaporin incorporated polyamide layer was characterized with AFM. • The effects of high pressure compaction and salinity on aquaporin incorporated polyamide layer were investigated. • The aquaporin based biomimetic membranes were optimized for seawater desalination (SWRO) application. • A seven-day SWRO measurement of the ASW was conducted using a real seawater secondary effluent. [ABSTRACT FROM AUTHOR]
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- 2019
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12. Design and development of layer-by-layer based low-pressure antifouling nanofiltration membrane used for water reclamation.
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Li, Xin, Liu, Chang, Yin, Wenqiang, Chong, Tzyy Haur, and Wang, Rong
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POLYETHYLENEIMINE , *WATER reuse , *WATER use , *GLUTARALDEHYDE , *NANOFILTRATION , *DISSOLVED organic matter , *REVERSE osmosis , *CHEMICAL stability - Abstract
Recent studies have confirmed the advantages of low-pressure nanofiltration (NF) membranes in integrated nanofiltration membrane bioreactor system followed by the reverse osmosis (RO) process for high recovery water reclamation. However, fouling of low-pressure NF membranes restricts their application in providing high quality feed to subsequent RO process. In this study, an antifouling low-pressure NF membrane was designed and fabricated via rapid co-deposition of polydopamine (PDA)/polyethylenimine (PEI) on electrostatic layer-by-layer (LBL) assembled polyethersulfone (PES) flat sheet membrane followed by crosslinking with glutaraldehyde. The optimized resultant membrane (LBL-cPP) presented approximately 11 LMH/bar pure water permeability with more than 90% rejection divalent cations under 2 bar pressure. The newly developed selective layer exhibited excellent antifouling performance and chemical stability ascribing to the inherent hydrophilicity of PDA/PEI and dual covalent reaction of PDA with the LBL layer. By feeding real municipal wastewater, the LBL-cPP membrane also achieved superior permeate quality, leading to lower RO fouling rate in subsequent RO unit as compared to commercial NF 270 membrane. Further organic foulant analysis indicated that 96.8% of dissolved organic carbons were effectively removed by the LBL-cPP membrane. Specifically, the novel NF membrane demonstrated high removal rate (>93%) for foulants with low molecular weights which was largely responsible for RO fouling, while maintaining the desired flux recovery rate and reduced cleaning frequency. This study demonstrates the potential of PDA/PEI modified low-pressure NF membranes in designing efficient and sustainable water reclamation technology. Image 1 • Novel low-pressure antifouling NF membrane was designed. • The selective layer was formed by co-deposition of PDA/PEI on LBL assembly layer. • Structural stability was improved via electrostatic and covalent interactions. • The developed NF membrane exhibited enhanced hydrophilicity and cations rejection. • Antifouling ability in water reclamation was evaluated with municipal wastewater. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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13. Polymersomes-based high-performance reverse osmosis membrane for desalination.
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Qi, Saren, Fang, Wangxi, Siti, Winna, Widjajanti, Wentalia, Hu, Xiao, and Wang, Rong
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POLYMERSOMES , *REVERSE osmosis , *SALINE water conversion , *COPOLYMERS , *POLYMERIZATION - Abstract
Polymersomes-based reverse osmosis (RO) membrane (PBM) for desalination was reported for the first time. An amphiphilic tri-block copolymer, PMOXA 6 -PDMS 35 -PMOXA 6 (ABA) , was self-assembled to form polymersomes with spherical nanostructure. The polymersomes were then immobilized into a polyamide network via an interfacial polymerization reaction on top of polysulfone membrane substrate. Under a moderate salinity condition, the PBM presented almost doubled water permeability and higher salt rejection than the control membrane without polymersomes in the polyamide network. Based on the results of a series of characterization the better water permeation of the PBM is believed to result from larger globular features containing highly water permeable polymersomes, which created a higher void fraction in the selective layer, whereas the highly cross-linked polyamide selective layer as well as the polymersome bilayer’s impermeability to NaCl may led to the enhanced salt rejection. Surprisingly, at an elevated NaCl concentration up to 32,000 ppm, the PBM exhibited ~ 60% water flux enhancement and even better NaCl rejection as compared with commercial seawater RO membranes. In general, the PBM presented a water flux similar to the RO membranes with loose polyamide matrix (BW30), but a rejection behavior close to the dense RO membranes (SW30). This study provides a paradigm shift in developing new-generation RO membranes for energy and cost-effective desalination process. [ABSTRACT FROM AUTHOR]
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- 2018
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14. Removal of haloacetic acids from swimming pool water by reverse osmosis and nanofiltration.
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Yang, Linyan, She, Qianhong, Wan, Man Pun, Wang, Rong, Chang, Victor W.-C., and Tang, Chuyang Y.
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SWIMMING pools , *NANOFILTRATION , *REVERSE osmosis , *MOLECULAR weights , *ELECTROSTATIC interaction - Abstract
Recent studies report high concentrations of haloacetic acids (HAAs), a prevalent class of toxic disinfection by-products, in swimming pool water (SPW). We investigated the removal of 9 HAAs by four commercial reverse osmosis (RO) and nanofiltration (NF) membranes. Under typical SPW conditions (pH 7.5 and 50 mM ionic strength), HAA rejections were >60% for NF270 with molecular weight cut-off (MWCO) equal to 266 Da and equal or higher than 90% for XLE, NF90 and SB50 with MWCOs of 96, 118 and 152 Da, respectively, as a result of the combined effects of size exclusion and charge repulsion. We further included 7 neutral hydrophilic surrogates as molecular probes to resolve the rejection mechanisms. In the absence of strong electrostatic interaction (e.g., pH 3.5), the rejection data of HAAs and surrogates by various membranes fall onto an identical size-exclusion (SE) curve when plotted against the relative-size parameter, i.e., the ratio of molecular radius over membrane pore radius. The independence of this SE curve on molecular structures and membrane properties reveals that the relative-size parameter is a more fundamental SE descriptor compared to molecular weight. An effective molecular size with the Stokes radius accounting for size exclusion and the Debye length accounting for electrostatic interaction was further used to evaluate the rejection. The current study provides valuable insights on the rejection of trace contaminants by RO/NF membranes. [ABSTRACT FROM AUTHOR]
- Published
- 2017
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15. Fabrication of fluorinated polyamide seawater reverse osmosis membrane with enhanced boron removal.
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Li, Can, Zhao, Yali, Lai, Gwo Sung, and Wang, Rong
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REVERSE osmosis , *POLYAMIDES , *SEAWATER , *BORON , *INTERFACIAL reactions , *PORE size distribution - Abstract
Developing a reverse osmosis membrane with desirable water/salt selectivity and boron removal has been recognized as crucial for high-efficient seawater desalination. Herein, fluorinated seawater reverse osmosis (SWRO) membranes were fabricated via fluorine-containing monomers-mediated interfacial polymerization or surface modification by grafting fluorine-containing monomers atop nascent polyamide (PA) layer via a second interfacial reaction. The fluorinated molecules, 5-(trifluoromethyl)-1.3-phenylenediamine (TFPD), 3,5-bis(trifluoromethyl) benzoyl chloride (TFBC) or 2,2,2-trifluoroethylamine (TFEA), were confirmedly integrated into the PA matrix presumably via strong chemical covalent bonds, which manipulated the physicochemical properties of the PA layer, including surface hydrophilicity, pore size distribution, cross-linking degree and interactions between membrane and solutes, thereby producing a high-selectivity thin-film composite (TFC) membrane. The optimized membranes, i.e. , TFC-TFPD, TFC-TFBC and TFC-TFEA, presented significantly excellent separation performance than the control and commercial membrane, both in water/salt selectivity and boron removal capability, accompanied by a comparable water permeance. Among the three proposed incorporation method of fluorinated monomers, direct grafting of TFEA upon the nascent PA layer demonstrates the best efficiency in introducing fluorine elements in the TFC PA membranes, compared to the addition of TFPD and TFBC into aqueous and organic phases during IP process, respectively. The fluorine-incorporated strategy employed in this present work offered a new design of the PA layer containing fluorinated molecules to obtain the desired permselectivity of TFC SWRO membranes towards efficient removal of salt and boron acid in seawater desalination. [Display omitted] • The fluorinated PA-based TFC SWRO membranes were successfully developed. • The fluorine-containing monomers were covalently bonded with PA matrix without sacrificing its integrity. • The incorporation of fluorine elements effectively regulated physicochemical properties of the PA layer. • The in-situ integrated fluorine components enabled high-efficient water/salt selectivity and boron removal. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
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16. A scalable method to fabricate high-performance biomimetic membranes for seawater desalination: Incorporating pillar[5]arene water nanochannels into the polyamide selective layer.
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Lim, Yu Jie, Lai, Gwo Sung, Zhao, Yali, Ma, Yunqiao, Torres, Jaume, and Wang, Rong
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SALINE water conversion , *COLUMNS , *SEAWATER , *REVERSE osmosis , *POLYAMIDES , *ENERGY consumption , *MILITARY communications - Abstract
In this work, we explored the practicability of a nanochannel-based biomimetic membrane (NBM) incorporating pillar[5]arene water channels for seawater reverse osmosis (SWRO) desalination. Two classes of peptide-attached biomimetic channels, (pR)-pillar[5]arenes (pRPH) and (pS)-pillar[5]arenes (pSPH) were integrated into the selective layer of SWRO membranes via interfacial polymerization on the top side of a polysulfone (PSf) support membrane. Here, pSPH is a non-identical stereoisomer of pRPH and was used as a negative control to pRPH to elucidate the flux enhancement effect contributed by pRPH. The optimized NBM presented a water permeability of 2.52 L m-2 h-1 bar-1 and 99.5% rejection under SWRO testing conditions of 50 bar applied pressure and 32,000 mg/L NaCl as feed solution. The 62% permeability increment with reference to the control membrane is hypothesized to originate from hybrid polyamide layers that were rougher with more voids (higher effective surface area and lower hydraulic resistance for water transport) as well as the conceivable water transport pathways provided by the pRPH channels. The simulation results from module-scale modelling suggest that the optimized NBM could lead to 7.2% savings in specific energy consumption of the membrane unit stage (or reduce the required membrane area by 25%) with respect to the commercial SWC4-LD membrane. The performance of the optimized NBM was further assessed in a one-week desalination test using an actual seawater feed gathered from an SWRO plant in Singapore. The robust NBM exhibited stable performance and ∼28% higher water flux (42 L m-2 h-1) than SWC4-LD with a comparable rejection of 99.3%, suggesting the feasibility of pillar[5]arene-based biomimetic membranes for seawater desalination. [Display omitted] • pRPH nanochannel-based biomimetic membrane (NBM) was used for SWRO application. • pRPH channels were incorporated into the PA layer via interfacial polymerization. • High permeability of 2.52 Lm-2h-1bar-1 (99.5% NaCl rejection) was reported in SWRO. • The energy and footprint savings achievable was quantified by module-scale modelling. • The NBM exhibited stable flux in a 7-day desalination test using real seawater. [ABSTRACT FROM AUTHOR]
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- 2022
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17. Dissecting the structure-compaction-performance relationship of thin-film composite polyamide membranes with different structure features.
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Zhao, Yali, Lai, Gwo Sung, Chong, Jeng Yi, and Wang, Rong
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POLYAMIDE membranes , *COMPOSITE membranes (Chemistry) , *POLYAMIDES , *REVERSE osmosis , *BRACKISH waters , *COMPACTING - Abstract
Thin film composite (TFC) polyamide (PA) membranes experience compaction at high pressure applications, resulting in the reduction in water permeability. However, the compaction mechanism is still unclear especially for different PA morphologies and substrate structures. In this work, we systematically studied the compaction of TFC PA membranes with different structures and morphologies. We first examined 2 main types of commercial reverse osmosis (RO) membranes: brackish water RO and seawater RO membranes. After that, we synthesised four types of TFC membranes with tailored PA and substrate structures to further understand the compaction behaviors. TFC membrane with a PA layer of low protuberances or nodules and dense substrate showed excellent resistance against high pressure (50 bar), with only a slight irreversible decrease of 2.1–3.5% in water permeability when retested at 5 bar. However, the PA layer of high protuberances experienced significant compaction even when it was supported by a similar dense substrate. The permeability of the TFC membrane decreased ∼10% as a result of the decrease in the effective area of the active layer. On the other hand, the TFC membrane with a PA layer of low protuberances formed atop a loose substrate showed a greater decrease (∼18.5%) in water permeability. The densified skin layer and collapsed macro-voids within the loose substrate resulted in a ∼40% decrease in the overall height of the PA layer and a 65% decline in substrate surface porosity, respectively, which are identified as the reasons for the reducing water permeability. Notably, the water-salt selectivity of this particular membrane was seriously deteriorated after compaction due to the presence of subtle defects in the PA layer caused by the drastic deformation of the loose substrate. This work deepens the understanding of the compaction behaviors of TFC PA membranes, providing a clear fundamental guidance on designing membranes applied at high operating pressures. [Display omitted] • The compaction of TFC PA membranes with different PA and substrate structures at 50-bar hydraulic pressure was investigated. • The high protuberances on the PA layer were compressed at 50 bar, resulting in an apparent decline in water permeability. • A porous substrate resulted in the decreases of water permeability and selectivity simultaneously after membrane compaction. • A TFC membrane with a low-protuberance PA layer and dense substrate is suitable for use in high-pressure processes. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
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18. Assessing the potential of highly permeable reverse osmosis membranes for desalination: Specific energy and footprint analysis.
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Lim, Yu Jie, Ma, Yunqiao, Chew, Jia Wei, and Wang, Rong
- Subjects
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REVERSE osmosis , *SALINE water conversion , *HOLLOW fibers , *MEMBRANE permeability (Biology) , *BRACKISH waters , *FLUID dynamics , *SEAWATER salinity - Abstract
The ultra-permeable membranes (UPMs) are expected to reduce the specific energy consumption (SEC) of desalination, but the potential of UPMs in hollow fiber configuration has not been well quantified. Herein, we analyse the SEC and footprints of UPM modules in three feed salinities: seawater reverse osmosis (SWRO), brackish water RO (BWRO) and low-pressure RO (LPRO). Through the modelling the fluid dynamics and mass transport of RO systems, we find that a tripling in spiral-wound SWRO membrane permeability (based on the current value of 1 L m−2 h−1 bar−1; LMH/bar) could result in 16% decrease in SEC. Contrastingly, the quadrupling of hollow fiber SWRO membrane permeability (based on the current value of 0.25 LMH/bar) could reduce the SEC by 23%. According to our analysis, hollow fiber and spiral-wound SWRO membranes with permeabilities up to 1 LMH/bar and 3 LMH/bar, respectively, can reduce the SEC of seawater desalination. On the other hand, membranes with permeabilities up to 9 LMH/bar and 12 LMH/bar can lead to SEC savings in BWRO and LPRO desalination, respectively. This study provides a general guidance to RO membrane researchers on the permeability upper-limit of which UPMs could bring about SEC and footprint savings at a system level. [Display omitted] • Energy savings achievable by high permeability RO membranes were quantified. • Modelling was performed by simulating fluid dynamics in various RO configurations. • Hollow fiber SWRO membranes (up to 1 LMH/bar) could reduce energy consumption. • Spiral-wound SWRO membranes (up to 3 LMH/bar) could reduce energy consumption. • High permeability RO membranes could bring about greater benefits in BWRO/LPRO. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
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19. Molecular dynamics simulation of the competitive adsorption behavior of effluent organic matters by heated aluminum oxide particles (HAOPs).
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Ma, Yunqiao, Hua, Tao, Trinh, Thien An, Wang, Rong, and Chew, Jia Wei
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COMPETITION (Psychology) , *ALUMINUM oxide , *ORGANIC compounds , *DYNAMICS , *MOLECULAR dynamics , *REVERSE osmosis , *BOUNDARY layer (Aerodynamics) , *STERIC hindrance - Abstract
[Display omitted] • Competitive adsorption of EfOM constituents by HAOPs visualized by MD simulation. • Foulant-adsorbent interaction energies are well correlated with removal efficiency. • EfOM anchor onto HAOPs despite steric hindrance due to higher foulant concentration. • Low mobility and flexibility of adsorbed foulants are tied to strong adsorption. Fouling mitigation of reverse osmosis membranes using various pre-treatment methods has received tremendous attention in the past years. The use of dynamic membranes particularly composed of heated aluminum oxide particles (HAOPs) appears to be a promising approach. Based off adsorption behaviors by individual foulants revealed by molecular dynamics (MD) simulations in an earlier study, this study targeted to understand the competitive adsorption of different constituents of effluent organic matters (EfOM) on HAOPs, which mimics the high local foulant concentration at the boundary layer. Quantitative analysis reveals that (i) EfOM constituents, except for low-molecular-weight neutrals, exhibit means to anchor onto HAOPs despite steric hindrance; (ii) adsorbed foulants exhibit significantly lower mobility and flexibility, indicating excellent adsorption capability of HAOPs before the dynamic membrane layer becoomes fully saturated with EfOM; and (iii) divalent ions and carboxylic group play critical roles in facilitating the adsorption of foulants. The MD results provide molecular-level mechanistic insights on the superior pre-treatment effectiveness by HAOPs. [ABSTRACT FROM AUTHOR]
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- 2022
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20. Investigation of aqueous and organic co-solvents roles in fabricating seawater reverse osmosis membrane.
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Li, Can, Zhao, Yali, Lai, Gwo Sung, and Wang, Rong
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- *
REVERSE osmosis , *SEAWATER , *ARAMID fibers , *BRACKISH waters , *SALINE water conversion , *INTERFACIAL tension , *POLYMERIZATION - Abstract
The addition of co-solvents in aqueous or organic phases of interfacial polymerization is a feasible strategy to tune the performance of aromatic polyamide (PA) thin-film composite (TFC) membrane for brackish water desalination, however, limited progress has been made in developing co-solvent-tailored seawater reverse osmosis (SWRO) membrane. Herein, SWRO membranes were prepared by adding various types of aqueous and organic co-solvents to reveal their impacts on the formation of the PA crumples. It was found that the aqueous/organic co-solvents affected the solubility parameter distance and interfacial tension between two immiscible phases, facilitating the diamine diffusion rate and resulting in a significant change in PA structure. The PA layer with modulated microstructure and varied surface features such as widened void structure, rougher surface, better wettability, and controlled cross-linking degree can be derived from the high interfacial instability that existed between the co-solvent and initial PA film due to the close mutual affinity. Besides, the additional polyvinyl alcohol coating layer atop the PA membrane successfully further enhanced the membrane selectivity. Overall, the mechanistic insights attained in this study revealed the relationship of diamine diffusion, physicochemical properties of PA layer and membrane separation performance for co-solvent-assisted membrane fabrication to render resultant SWRO membrane with more comparable permselectivity. The optimized TFC-SWRO membranes exhibited pure water permeability of 2.2 and 3.2 L m−2 h−1 bar−1 upon the assistance of aqueous and organic co-solvents, respectively, while maintaining excellent NaCl rejection of approximately 99% under seawater desalination tests. [Display omitted] ✓ Aqueous or organic co-solvents were used aiming to flexibly design high-performance SWRO membrane. ✓ The synergistic impacts of solubility parameter and interfacial tension were established to elucidate diamine diffusion behavior. ✓ The relationship of "monomer diffusion - structure property - separation performance" was elaborated. ✓ The formation of a PVA coating layer enhanced the selectivity of co-solvent-assisted SWRO membrane. [ABSTRACT FROM AUTHOR]
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- 2022
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21. Organic solvent forward osmosis membranes for pharmaceutical concentration.
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Goh, Keng Siang, Chen, Yunfeng, Ng, Daniel Yee Fan, Chew, Jia Wei, and Wang, Rong
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ORGANIC solvents , *ISOPROPYL alcohol , *OSMOSIS , *HOLLOW fibers , *POLYIMIDES , *COMPOSITE membranes (Chemistry) , *REVERSE osmosis , *REVERSE osmosis process (Sewage purification) - Abstract
A scaled-up hollow fibre thin-film composite (TFC) module was successfully developed for organic solvent forward osmosis (OSFO) application in the pharmaceutical industry. The membrane consists of cross-linked P84 polyimide substrate with a polyamide selective layer, formed via interfacial polymerisation. The performance of the lab-scale module was compared to the scaled-up module in reverse osmosis and forward osmosis modes. The results from both tests revealed that the solvent permeability of the scaled-up module decreased while its selectivity increased slightly. This might be caused by the uneven distribution of liquids during interfacial polymerisation, leading to varied membrane performance. The scaled-up module was further tested for OSFO performance using a range of PEG-400 concentrations (0.5–2 M) in acetone and isopropanol as draw solutions. At 2 M PEG-400 concentration, the module demonstrated high isopropanol and acetone permeability of 0.63 LMH and 13.9 LMH, respectively. Moreover, the reverse solute flux of PEG-400 in acetone and isopropanol were relatively low at 0.188 g/l and 0.153 g/l, respectively. The module was further tested for OSFO application in the pharmaceutical industry by concentrating levofloxacin in acetone, using 2 M PEG-400 as draw solution. The process was able to concentrate levofloxacin from 1000 ppm to 16,000 ppm with very low reverse solute flux of 0.178 g/l. Therefore, this work presents a scalable TFC membrane for OSFO application in the pharmaceutical industry. [Display omitted] • Scaled-up module (0.4 m2) of TFC hollow fibre membrane for organic solvent forward osmosis process was successfully fabricated. • High porosity (79%) and low structural parameter (217 μm) for membrane substrate was achieved. • Membrane exhibited excellent acetone and IPA solvent flux of 13.9 LMH and 0.63 LMH, respectively, using a 2 M PEG-400 draw solution. • A pharmaceutical stream was concentrated to a factor of 16 with low specific reverse solute flux [ABSTRACT FROM AUTHOR]
- Published
- 2022
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22. Unraveling the role of support membrane chemistry and pore properties on the formation of thin-film composite polyamide membranes.
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Lim, Yu Jie, Goh, Kunli, Lai, Gwo Sung, Zhao, Yali, Torres, Jaume, and Wang, Rong
- Subjects
- *
POLYETHERSULFONE , *POLYAMIDE membranes , *POLYAMIDES , *COMPOSITE membranes (Chemistry) , *POLYMERIC membranes , *REVERSE osmosis , *CHEMICAL reactions - Abstract
Nanoscale characteristics of the polyamide layer are key towards the high desalination performance of thin-film composite reverse osmosis (TFC-RO) membranes. Further advancements in the performance of TFC membranes necessitate a comprehensive understanding of the desired polyamide characteristics and its formation mechanisms. Empirical evidence has shown that the properties of the support layer is as equally important as the interfacial polymerization (IP) conditions in the fabrication of high permselectivity TFC membranes for desalination. Herein, we discuss the properties of polyamide layers formed using identical IP conditions over support membranes of different polymers and chemistries (polyethersulfone, polyetherimide and polysulfone) under fairly similar surface pore properties. The characteristics of the polyamide layers formed thereon displayed different physicochemical properties. It is postulated that the support membrane chemistry actually affects the IP reaction and polyamide formation by controlling the amine diffusion speed as well as the breadth of the IP reaction zone (i.e., the region between the interface and the furthest point in which the reaction occurs). Transmission electron microscopy analyses further revealed the nanoscale differences in the polyamide layer (heights ranging from 50 to 200 nm), including intrinsic thickness of basal layer (~10–35 nm) and leaf-like top layer (~20–85 nm), as well as the presence of nanovoids. Finally, we propose a conceptual model to underline the role of support membrane chemistry in the IP reaction, and consequently the formation mechanism of the nanoscale polyamide features. The mechanistic insights from this study are expected to provide more understanding towards a better control over the fabrication of polyamide layers for TFC membranes. The findings in this work are also expected to facilitate tailoring polyamide layers for specific osmotically driven processes. [Display omitted] • Support membrane chemistry affects MPD diffusion and partitioning extent in IP. • TEM and SEM analyses revealed changes in the polyamide (PA) nanoscale morphology. • PA layer of TFC-PES membrane was thin and smooth without any nanovoids. • PA layer of TFC-PSf membrane had thick base, thin leaves and multi-layer nanovoids. • PA layer of TFC-PEI membrane had thin basal layer with clumpy roof-like top layer. [ABSTRACT FROM AUTHOR]
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- 2021
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23. Impact of pilot-scale PSF substrate surface and pore structural properties on tailoring seawater reverse osmosis membrane performance.
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Zhao, Yali, Lai, Gwo Sung, Wang, Yining, Li, Can, and Wang, Rong
- Subjects
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SEAWATER , *REVERSE osmosis , *SURFACE properties , *POLYMER solutions , *THIN films - Abstract
Recent research pays much attention to the correlations between structural properties of porous substrate and the separation performance of polyamide (PA) thin film composite (TFC) membrane prepared by interfacial polymerization (IP). However, there are limited studies focused on seawater reverse osmosis (SWRO) membrane preparation and optimization. This study reveals profound impacts of substrate surface properties on the separation properties of SWRO membranes, by using different substrates including commercial ultrafiltration (UF) membrane, lab-scale casted polysulfone (PSF) substrate and pilot-scale casted PSF substrates. We demonstrate that the membrane substrates casted using pilot-scale machine led to better SWRO performance than hydrophilic UF membrane or lab-scale casted substrate; and very different SWRO membranes could be made from pilot-scale substrates casted using the same polymer dope solution. These results showed that a high-performance SWRO membrane relies on appropriate substrate possessing the surface properties of relatively hydrophobic, small surface pore size (20-35 nm) and high surface porosity, which directly affect the supply and transport rate of amine for the IP reaction. Our best SWRO membrane exhibits an excellent NaCl rejection of 99.5% together with high water permeance of 1.72 L m−2 h−1 bar−1 under seawater desalination conditions. This work helps pave the way for substrate selection for SWRO membrane fabrication, narrowing the gap between lab-made and commercial SWRO membranes. [Display omitted] • Substrates with tuned surface properties were used to tailor SWRO membrane performance. • PSF substrates casted by a pilot-scale machine exhibited better SWRO performance. • The best-performing membrane demonstrated water permeance of 1.72 Lm−2h−1bar−1 and rejection of 99.5%. • Hydrophobic substrate of small surface pore size and high surface porosity was important for making excellent SWRO membrane. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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24. Seawater desalination by reverse osmosis: Current development and future challenges in membrane fabrication – A review.
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Lim, Yu Jie, Goh, Kunli, Kurihara, Masaru, and Wang, Rong
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REVERSE osmosis , *SEAWATER , *COMPOSITE membranes (Chemistry) , *BRACKISH waters - Abstract
Seawater reverse osmosis (SWRO) is the key technology driving an energy-efficient and cost-effective desalination process. At the center of this technology are the thin film composite (TFC) membranes, which not only promise a stable operation but also high separation performances. The objective of this review is to consolidate recent advances in SWRO membranes from the standpoint of membrane materials, fabrication methodologies and applications. First, the thermodynamic limit and energy consumption of SWRO desalination are reviewed, before we discuss the current status of SWRO membranes, highlighting the four main challenges to date – permselective tradeoff, relatively low single-pass boron rejection, membrane fouling and poor chlorine resistance. Thereafter, a comprehensive review of the membrane development is presented. We examine findings reported in research papers and patents, and various methods to achieve SWRO membranes of higher permselectivity, boron rejection, and chlorine resistance as well as lower fouling propensity. Key insights from the membrane industry are also furnished. Then, we put together an outlook, featuring our perspectives on SWRO membrane development. Empirical data in this review are collated into an upper-bound relationship, which is tailored specifically for SWRO membranes and expected to provide benchmarking for future SWRO membrane development. Since the traits of SWRO membranes are unique from those of brackish water RO (BWRO) membranes, we also distinguish the methods used for SWRO membrane fabrication to help zero in on the correct strategies, and provide insights for advancing new membrane designs. Overall, this review sums up the current state-of-the-art SWRO membranes, looking at the array of fabrication methods used thus far, and putting into perspective critical strategies to realize the next-generation TFC membranes that can address the future demands of SWRO and deliver a more competitive desalination process. [Display omitted] • Recent advances in SWRO membrane are collated from papers and industrial patents. • Current status and future outlook of SWRO membrane industry are discussed. • A permselectivity upper bound is established specifically for SWRO membranes. • The upper bound is given by A/B = 46.75 A −1.72 (A/B in bar−1 and A in Lm−2h−1 bar−1). • A roadmap for SWRO membrane fabrication is proposed (short/long-term strategies). [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
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25. Organic matter removal from a membrane bioreactor effluent for reverse osmosis fouling mitigation by microgranular adsorptive filtration system.
- Author
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Chun, Youngpil, Hua, Tao, Anantharaman, Aditya, Chew, Jia Wei, Cai, Nathan, Benjamin, Mark, and Wang, Rong
- Subjects
- *
WATER filtration , *REVERSE osmosis , *ORGANIC compounds , *WATER reuse , *FOULING , *PLANT-water relationships - Abstract
In this study, a prototype microgranular adsorptive filtration (μGAF) system was constructed employing a 7-bore ceramic membrane as the primary membrane and either heated aluminum oxide particles (HAOPs) or powdered activated carbon (PAC) as the pre-deposited dynamic membrane (DM). The system was used to pre-treat membrane bioreactor (MBR) effluent from a full-scale MBR-reverse osmosis (RO) water reclamation plant. The downstream RO performance and membrane fouling potential of the treated effluent were then assessed. The results indicated that: (i) although PAC removed more overall EfOM than HAOPs did, HAOPs were more effective in removing biopolymers such as polysaccharides and proteins, (ii) HAOPs virtually eliminated fouling of the primary ceramic membrane, whereas considerable fouling (much of it irreversible) occurred when the feed was pretreated with PAC, (iii) HAOPs removed more than 90% of the phosphorus and fluoride from the feed, but PAC removed negligible amounts of these contaminants, and (iv) HAOPs-treated effluent resulted in only a 43% decline in RO permeate water flux over 5 d of continuous filtration, as opposed to 62% flux decline for untreated or PAC-treated effluent. This study thus demonstrates the effectiveness of the HAOPs-based μGAF process as a pre-treatment for improving downstream RO recovery. • A prototype μGAF system was used to treat an MBR effluent from a full-scale MBR-RO plant. • μGAF using HAOPs demonstrated an efficient removal of biopolymer, phosphorus, silica and fluoride. • HAOPs was more effective at mitigating downstream RO fouling compared to PAC. • HAOPs demonstrated the potential to enhance the overall performance of a water recovery process. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
26. Fast water transport through biomimetic reverse osmosis membranes embedded with peptide-attached (pR)-pillar[5]arenes water channels.
- Author
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Lim, Yu Jie, Goh, Kunli, Lai, Gwo Sung, Ng, Chiann Yi, Torres, Jaume, and Wang, Rong
- Subjects
- *
REVERSE osmosis , *AROMATIC compounds , *FEED additives , *LIPOSOMES , *COMPOSITE membranes (Chemistry) , *SALT , *PERMEABILITY , *POLYAMIDES - Abstract
This study examined the feasibility and performance of a nanochannel-based biomimetic membrane (NBM) for brackish reverse osmosis (RO) desalination. Two types of peptide-attached synthetic nanochannels, (pR)-pillar[5]arenes (pRPH) and (pS)-pillar[5]arenes (pSPH), were incorporated into liposomes. pSPH is a diastereomer of pRPH and was used as a negative control (i.e. mutant) to pRPH in this work. The nanochannel-containing liposomes (e.g. pRPH-liposomes) were then immobilized into the active layer of the RO membranes via in situ interfacial polymerization on the top of a polysulfone support membrane to form NBM-pRPH membranes. To maximize the potential and benefits of the NBM-pRPH membrane, the physical characteristics of the polyamide layer was further tuned using some additives and the eventual membrane was named as NBM-pRPH-A. The NBM-pRPH-A membrane exhibited a water permeability of 6.09 L m−2 h−1 bar−1 and 98.2% NaCl rejection under a 15.5 bar applied pressure using 2000 mg L−1 as feed solution. The 62% flux increment with respect to the pristine control is postulated to arise from a thinner, less cross-linked (more free volume) and more hydrophilic active layer as well as the possible supplementary transport pathways of the pRPH-liposomes. The performance of the NBMs under differential feed pressures and temperatures further exemplifies the water permeation property of the pRPH nanochannels. Accordingly, the NBM-pRPH-A gave a water permeability higher than commercial RO membranes tested in this work (DuPont BW30 and Hydranautics ESPA2) as well as other RO membranes reported in the literature. This study provides a tangible foundation for the development of NBMs for brackish RO desalination. [Display omitted] • Synthetic pRPH nanochannel-based biomimetic membrane was used for BWRO application. • pRPH-liposomes were incorporated onto the PA layer via interfacial polymerization. • STEM-EDX analysis revealed the existence of liposomes in the PA layer. • High permeability of 6.09 Lm−2h−1bar−1 (98.2% NaCl rejection) was reported in BWRO. • RO tests under increasing ΔP and temperature suggested water transport across pRPH. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
27. A biomimetic antimicrobial surface for membrane fouling control in reverse osmosis for seawater desalination.
- Author
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Tian, Miao, Xu, HuiJuan, Yao, Lei, and Wang, Rong
- Subjects
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REVERSE osmosis , *FOULING , *SEAWATER , *SURFACE roughness , *POLYAMIDE membranes , *MEMBRANE separation - Abstract
Membrane fouling occurs in all membrane processes. Surface modifications have gained popularity for enhancing membrane antifouling capability via introducing a hydrophilic component or reducing membrane surface roughness. In this work, we proposed to develop a green antimicrobial lysozyme nanofilm on the polyamide membrane surface with remarkable antibacterial and antifouling properties to effectively reduce membrane fouling. The nanofilm is rooted in the molecular assembly of a protein which is an extraction of food and natural products. The nanofilm exhibits the combination of various functions including antimicrobial, antifouling and antibiofilm. This protein-based nanofilm is robustly transferred and self-adhered on the membrane surface by a simple one-step aqueous coating. The modified RO membrane exhibited good performance in bacterial reduction of ~50% in comparison to the control membrane and experienced almost zero loss in water flux and salt rejection under SWRO testing condition. The membrane is further evaluated with real seawater for 14 days and the modified membrane showed its superiority in flux and fouling control which were verified by the confocal laser scanning microscopy (CLSM) and quantified by inductively coupled plasma optical emission spectrometer (ICP-OES). This work demonstrates that the protein-based biomaterials offer a safe and environmentally friendly way of antimicrobials, which can reduce membrane fouling significantly in membrane filtration. Unlabelled Image • A protein-based antimicrobial nanofilm was in-situ fabricated on a commercial SWRO membrane surface. • The modification did not change the SWRO membrane's selectivity and water permeability. • The modified membrane demonstrated ~50% bacterial reduction compared to the control membrane. • The modified membrane had good anti-fouling property applied in SWRO. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
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28. Use of rigid cucurbit[6]uril mediating selective water transport as a potential remedy to improve the permselectivity and durability of reverse osmosis membranes.
- Author
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Lee, Jaewoo, Zhou, Feng, Baek, Kangkyun, Kim, Wooram, Su, Haibin, Kim, Kimoon, Wang, Rong, and Bae, Tae-Hyun
- Subjects
- *
QUANTUM mechanics , *ACTIVATION energy , *WATER , *DURABILITY , *SALINE waters , *REVERSE osmosis - Abstract
In spite of many efforts to grasp the nature of porous nanomaterials, it is hard to find research work addressing empirical evidence for selective water permeation through their channels or pores. Herein, we report the experimental proof of selective water permeation through cucurbit[6]uril (CB[6]) with a portal diameter of 3.9 Å along with quantum mechanics calculation results elucidating the mechanisms underlying the selective water transport. CB[6] improved the water/salt permselectivity of CB[6]-polyamide thin-film nanocomposite (CB[6]-TFN) membranes since ion passage was inhibited by a high energy barrier imposed by the CB[6]'s portals while the portals are energetically favorable from the perspective of water transport. This difference in water and salt's permeabilities stems from its carbonyl-fringed portals, which are cut out for size exclusion and negatively charged for charge repulsion. Due to the rigidity, CB[6]-TFN membranes were found to be more resistant to compaction under elevated pressures. Such unique characteristics of CB[6] allowed CB[6]-TFN membranes to outperform newly developed TFN membranes as well as commercial RO membranes. Image 1 • CB[6] (Cucurbit[6]uril) is suitable for water transport while preventing ion passage. • The carbonyl-fringed portals have the right dimension for size exclusion. • The carbonyl-fringed portals are negatively charged for charge repulsion. • CB[6] improved the permselectivity of thin-film nanocomposite (TFN) membranes. • A CB[6]-TFN membrane was more resistant to compaction due to the rigidity. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
29. Feasibility and performance of a thin-film composite seawater reverse osmosis membrane fabricated on a highly porous microstructured support.
- Author
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Lim, Yu Jie, Lee, Jaewoo, Bae, Tae-Hyun, Torres, Jaume, and Wang, Rong
- Subjects
- *
SEAWATER , *REVERSE osmosis , *COMPOSITE membranes (Chemistry) , *PERMEABILITY , *STRESS concentration , *DIFFUSION - Abstract
Although a highly porous support membrane has attracted increasing attention as an alternative to enhance the water permeability of a thin-film composite (TFC) membrane without compromising salt rejection, its feasibility has not ever been tested in seawater desalination. This study explored the availability and potential of a highly porous microstructured (HPμS) support membrane as a support for a seawater reverse osmosis (SWRO) membrane. Our lab-made membranes, TFC-HPμS, exhibited a higher water permeability of 1.62 L m−2 h−1 bar−1 as compared with most of the state-of-the-art SWRO membranes recently reported in the literature, while achieving comparable NaCl rejection (99%) in SWRO test condition (55 bar, 35,000 mg L−1 of NaCl). This excellent performance is thought to stem from the HPμS support endowing a TFC membrane with comparable mechanical properties to that of existing support used for conventional SWRO membrane and shortened effective diffusion pathway of water molecules over the active layer. The robustness and enhanced mechanical strength of the TFC-HPμS membrane are attributed to its narrow and regularly arranged finger-like structure ensuring the even distribution of local stresses, thereby eliminating the presence of stress convergence points. The shortened effective diffusion pathway was estimated to be achieved mainly by less localized surface pores due to the HPμS support's highly porous surface with a larger number of even distributed surface pores. This study potentially opens up another workable pathway in the fabrication of SWRO membranes with enhanced performance without significant sacrifice of the selectivity. • Highly porous microstructured support membrane was used for seawater desalination. • The regularly arranged sublayer enhanced the mechanical strength of the support. • The effective diffusion pathway can be shortened with less localized surface pores. • The tuned TFC membrane exhibited higher permselectivity as compared to the control. • High permeability of 1.62 Lm−2h−1bar−1 (>99% NaCl rejection) was reported in SWRO. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
30. Pre-deposited dynamic membrane filtration – A review.
- Author
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Anantharaman, Aditya, Chun, Youngpil, Hua, Tao, Chew, Jia Wei, and Wang, Rong
- Subjects
- *
MEMBRANE separation , *INDUSTRIAL wastes , *MICROFILTRATION , *WATER purification , *REVERSE osmosis process (Sewage purification) , *ORGANIC conductors , *METALLIC oxides , *REVERSE osmosis - Abstract
A dynamic membrane (DM) is a layer of particles deposited via permeation drag onto a conventional membrane, such that the deposited particles act as a secondary membrane that minimizes fouling of the primary membrane to lower transmembrane pressures (TMP) and enable higher permeate fluxes. Since the first DM was created in 1966 at the Oak Ridge National Laboratory, numerous studies have reported synthesis of DMs using various materials and explored their abilities to perform reverse osmosis (RO), nanofiltration (NF), ultrafiltration (UF) and microfiltration (MF). DMs are classified into two categories, namely, (i) self-formed, whereby the feed constituents form the DM; and (ii) pre-deposited, whereby the DM is formed by a layer of particles other than the feed prior to introduction of the feed. This paper endeavors to present a comprehensive review of the state-of-the-art on the latter. Key materials used as DMs, their formation and various factors influencing it, regeneration of DMs and modifications to DM systems for performance enhancement are discussed. The role of DMs in preventing fouling in the primary membrane (PM) is explained. The applications of DMs in four major areas, namely, salt and organic solute rejection, treatment of industrial effluents, treatment of water and wastewater, and oily-wastewater treatment are reviewed. Furthermore, technical and economic advantages of DMs over conventional processes are considered, and challenges in current DM research are discussed. Finally, directions for future research are suggested. Image 1 • Comprehensive review of 148 publications on pre-deposited dynamic membranes (DMs). • DM material, support structure, cross-flow velocity and pH affect DM formation. • Metal oxides, polymers and dual metal oxide-polymer layers are most common DMs. • Developed for reverse osmosis, now used in organics removal and fouling mitigation. • Nanoparticles are recent versatile DM materials and promising in fouling mitigation. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
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