期刊
JOURNAL OF MEMBRANE SCIENCE
卷 661, 期 -, 页码 -出版社
ELSEVIER
DOI: 10.1016/j.memsci.2022.120952
关键词
Thin-film nanocomposite membrane; Nanomaterial; Selectivity; Water permeance; Membrane modification
资金
- Na- tional Natural Science Foundation of China [52170010]
- Shanghai Pujiang Program [21PJD073]
This study critically summarizes the roles of nanomaterials with different dimensions and positions in the construction of thin-film nanocomposite (TFN) membranes. The efficacy of nanomaterial incorporation in tailoring membrane properties and separation performance is analyzed through the evaluation of water permeance, water/salt selectivity, and characterization parameters of TFN membranes.
Nanomaterials with diverse dimensions have been incorporated in different positions during the development of novel thin-film nanocomposite (TFN) membranes for water and wastewater treatment. However, a compre-hensive comparison and rational selection are yet to be attained. According to the incorporation positions of nanomaterials, i.e., in the active layer, in the support layer and at the interface between the two, the membranes can be classified into TFNa, TFNs, and TFNi membranes, respectively. In this study, the roles of incorporation positions and dimensions of nanomaterials in TFN membrane construction are critically summarized, covering 187 pairs of optimal TFN membranes and corresponding control membranes reported in the literature. The water permeance, water/salt selectivity and characterization parameters of these membranes were mainly analyzed to compare the efficacy of nanomaterial incorporation in tailoring membrane properties and separation perfor-mance. Some instructive results demonstrated, for example, that TFNa membranes for reverse/forward osmosis and TFNi membranes for nanofiltration were superior in terms of overcoming the trade-off between water permeance and selectivity. In preparation of TFNi and TFNs membranes, utilization of 1D or 2D nanomaterials was more conducive to achieving an excellent water/salt selectivity than nanoparticles. This review can provide guidance for the targeted construction of high-performance TFN membranes.
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