Enhancing antifouling capability of PES membrane via mixing with various types of polymer modified multi-walled carbon nanotube

Daraei, Parisa; Madaeni, S.S.; Ghaemi, Negin; Khadivi, Mohammad Ali; Astinchap, Bandar; Moradian, Rostam

doi:10.1016/j.memsci.2013.05.020

Cited by 162 publications

(61 citation statements)

References 33 publications

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“…Meanwhile, the much smoother surface, small pore size and high LEP of G/PVDF-0.5 could have lessen the chances of heterogeneous nucleation on the surface, and prohibit the penetration of salts into the pore depth; hence lower tendency for scaling occurred [37,38]. Even at low flow velocity, the scales could have been constantly removed by the flow shear force thereby leaving the surface clean for longer period of time.…”

Section: (Figure 8)mentioning

confidence: 99%

Graphene/PVDF flat-sheet membrane for the treatment of RO brine from coal seam gas produced water by air gap membrane distillation

Woo

Kim

Shim

et al. 2016

Journal of Membrane Science

122

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. (2016). Graphene/PVDF flat-sheet membrane for the treatment of RO brine from coal seam gas produced water by air gap membrane distillation. Journal of Membrane Science, 513 74-84.Graphene/PVDF flat-sheet membrane for the treatment of RO brine from coal seam gas produced water by air gap membrane distillation Keywords brine, ro, distillation, treatment, gap, membrane, sheet, flat, pvdf, graphene, air, water, produced, gas, seam AbstractBrine management of coal seam gas (CSG) produced water is a significant concern for the sustainable production of CSG in Australia. Membrane distillation (MD) has shown the potential to further reduce the volume of CSG reverse osmosis (RO) brine. However, despite its potential, the lack 2 of appropriate MD membranes limits its industrial use. Therefore, this study was aimed on the

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Section: (Figure 8)mentioning

confidence: 99%

Graphene/PVDF flat-sheet membrane for the treatment of RO brine from coal seam gas produced water by air gap membrane distillation

Woo

Kim

Shim

et al. 2016

Journal of Membrane Science

122

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“…The growth of cake layer on the membrane surface will form and reduce the flux permeation and consequently, decrease the value of FRR. This can be considered as the impact of membrane fouling which leads to an increase in hydraulic resistance and reduction of filtration efficiency [16][17][18].…”

Section: Figure 4 Flux Recovery Ratio (Frr) Reversible Fouling Ratimentioning

confidence: 99%

Preparation, Characterization and Performance of Polyvinylidene Fluoride/Tetraoctyl Phosphonium Bromide Nanocomposite Ultrafiltration Membrane

Ali¹,

Yu²,

Sani³

et al. 2018

MJAS

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“…Poly(trimethylene terephthalate) (PTT) nanofiber membrane Li et al (2013), Xue et al (2010) Thin film composite (TFC) membrane Han (2013) PSf membrane Crock et al (2013), Zhao et al (2011) Poly ( Polyethersulfone (PES) membrane Madaeni and Bakhtiari (2012), Rahimpour et al (2012), Daraei et al (2013) Poly(amide-imide) (PAI) hollow fibre membrane Setiawan et al (2011), Zhang et al (2011 Ceramic asymmetric membrane Kim and der Bruggen (2010), DeFriend et al (2003), Tsuru et al (2001) Cellulose acetate blend membrane Han et al (2013), Mohammadi and Saljoughi (2009) Different morphological structures of these materials affect the glucose diffusivity though the materials.…”

Section: Membrane Type Schematic Of Cross-section Referencesmentioning

confidence: 99%

Glucose diffusion in tissue engineering membranes and scaffolds

Suhaimi

Das

2016

Reviews in Chemical Engineering

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Tissue engineering has evolved into an exciting area of research due to its potential in regenerative medicine. The shortage of organ donors as well as incompatibility between patient and donor pose an alarming concern. This has resulted in an interest in regenerative therapy where the importance of understanding the transport properties of critical nutrients such as glucose in numerous tissue engineering membranes and scaffolds is crucial. This is due to its dependency on successful tissue growth as a measure of potential cure for health issues that cannot be healed using traditional medical treatments. In this regard, the diffusion of glucose in membranes and scaffolds that act as templates to support cell growth must be well grasped. Keeping this in mind, this review paper aims to discuss the glucose diffusivity of these materials. The paper reviews four interconnected issues, namely, (i) the glucose diffusion in tissue engineering materials, (ii) porosity and tortuosity of these materials, (iii) the relationship between microstructure of the material and diffusion, and (iv) estimation of glucose diffusivities in liquids, which determine the effective diffusivities in the porous membranes or scaffolds. It is anticipated that the review paper would help improve the understanding of the transport properties of glucose in membranes and scaffolds used in tissue engineering applications.

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Enhancing antifouling capability of PES membrane via mixing with various types of polymer modified multi-walled carbon nanotube

Cited by 162 publications

References 33 publications

Graphene/PVDF flat-sheet membrane for the treatment of RO brine from coal seam gas produced water by air gap membrane distillation

Graphene/PVDF flat-sheet membrane for the treatment of RO brine from coal seam gas produced water by air gap membrane distillation

Preparation, Characterization and Performance of Polyvinylidene Fluoride/Tetraoctyl Phosphonium Bromide Nanocomposite Ultrafiltration Membrane

Glucose diffusion in tissue engineering membranes and scaffolds

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