2022
DOI: 10.3389/fchem.2022.781372
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Review of Thin Film Nanocomposite Membranes and Their Applications in Desalination

Abstract: All over the world, almost one billion people live in regions where water is scarce. It is also estimated that by 2035, almost 3.5 billion people will be experiencing water scarcity. Hence, there is a need for water based technologies. In separation processes, membrane based technologies have been a popular choice due to its advantages over other techniques. In recent decades, sustained research in the field of membrane technology has seen a remarkable surge in the development of membrane technology, particula… Show more

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Cited by 37 publications
(17 citation statements)
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“…[209][210][211] Of particular note, incorporating hydrophilic-rich nanomaterials into the PA layer, such as the Zinc oxide (ZnO) family including nanorods (R-ZnO), nanoflowers (F-ZnO) and nanospheres (S-ZnO), has been shown experimentally to improve the desalination performance. 212 Among these, the integrated S-ZnO/ TFC membranes provided the highest water flux with good salt rejection. 213 Similarly, the incorporation of carbon quantum dots (CQD) with the Na functional group into the PA layer has resulted in increased hydrophilicity with which better water permeability was obtained when desalting brackish water.…”
Section: Perspectivesmentioning
confidence: 99%
“…[209][210][211] Of particular note, incorporating hydrophilic-rich nanomaterials into the PA layer, such as the Zinc oxide (ZnO) family including nanorods (R-ZnO), nanoflowers (F-ZnO) and nanospheres (S-ZnO), has been shown experimentally to improve the desalination performance. 212 Among these, the integrated S-ZnO/ TFC membranes provided the highest water flux with good salt rejection. 213 Similarly, the incorporation of carbon quantum dots (CQD) with the Na functional group into the PA layer has resulted in increased hydrophilicity with which better water permeability was obtained when desalting brackish water.…”
Section: Perspectivesmentioning
confidence: 99%
“…TFC membranes are comprised of a non-woven fabric support layer on which a porous intermediate polymer (PES or PSf) layer (~50 nm) is combined with a thin, highly crosslinked dense PA layer (<200 nm) [ 35 , 49 , 50 ]. The top epidermal layer provides selectivity and/or separation while the porous substrate layer that is permeable to water and dissolved solute particles provides mechanical strength [ 32 , 51 ]. These membranes exhibit better salt rejection, higher water flux or permeability, and higher stability (chemical, mechanical and thermal) compared to commercially available cellulose-based membranes [ 50 , 51 , 52 , 53 ].…”
Section: Introductionmentioning
confidence: 99%
“…The interfacial interaction between nanomaterials and the polymer is an important factor which could control the reinforcing efficiency of nanocomposite membrane. Functionalization of the nanomaterials using several chemical groups could improve their homogenization inside the polymer matrix [38].…”
Section: Introductionmentioning
confidence: 99%