Scalable synthesis of ultrathin MoS2 membranes for dye desalination

IF 4.9 Q1 ENGINEERING, CHEMICAL
Rodrigo Schneider , Ameya Manoj Tandel , Erda Deng , Daniel S. Correa , Haiqing Lin
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引用次数: 0

Abstract

Molybdenum disulfide (MoS2) has been fabricated into thin-film composite (TFC) membranes for dye desalination due to its excellent underwater stability and tunable interlay spacing. However, it remains challenging to synthesize thin layers of MoS2 with high water permeance and high dye rejection due to the difficulty in fabricating large crystalline sheets or exfoliation. Herein, we report a scalable method coupling bottom-up hydrothermal synthesis and top-down ultrasonic exfoliation to obtain well-dispersed MoS2 nanosheets and a vacuum filtration method to prepare ultrathin membranes (thickness: 30 – 60 nm) for dye desalination. The MoS2 nanosheets and membranes are thoroughly characterized for their chemistries and nanostructures. The membrane with 60-nm MoS2 exhibits water permeance of 32 LMH/bar, Na2SO4 rejection of 2.3%, and Direct Red-80 rejection of 99.0%. The MoS2 membranes exhibit dye desalination performance superior to state-of-the-art commercial polyamide membranes and many leading membranes based on two-dimensional materials.

染料脱盐用超薄二硫化钼膜的规模化合成
二硫化钼(MoS2)具有良好的水下稳定性和可调的层间距,已被制备成用于染料脱盐的薄膜复合材料(TFC)膜。然而,由于难以制造大的结晶片或剥离,合成具有高透水性和高染料截留率的MoS2薄层仍然具有挑战性。在此,我们报道了一种可扩展的方法,将自下而上的水热合成和自上而下的超声剥离相结合,以获得分散良好的MoS2纳米片,以及一种真空过滤方法,以制备用于染料脱盐的超薄膜(厚度:30–60 nm)。对MoS2纳米片和膜的化学性质和纳米结构进行了全面表征。具有60nm MoS2的膜表现出32LMH/bar的透水性、2.3%的Na2SO4截留率和99.0%的Direct Red-80截留率。MoS2膜表现出优于最先进的商业聚酰胺膜和许多基于二维材料的领先膜的染料脱盐性能。
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CiteScore
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