Modulating low-temperature interfacial polymerization with NaHCO3 for high-performance ultrathin nanofiltration membranes

IF 4.1 2区工程技术 Q2 ENGINEERING, CHEMICAL

Chemical Engineering Science Pub Date : 2024-09-12 DOI:10.1016/j.ces.2024.120723

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Abstract

Conventional interfacial polymerization (IP) encounters significant challenges in achieving the desired nanofiltration (NF) membrane structure, owing to uncontrolled diffusion and ultrafast polymerization. Our study introduced carbonates into the low-temperature interfacial polymerization (LTIP) process to precisely regulate the diffusion of amine monomers and polymerization kinetics. Carbonates in the aqueous phase restrict the diffusion of amine monomers while promoting the generation of nanobubbles. Further utilization of the low-temperature oil phase not only retards polymerization but also facilitates the formation of foam nanostructures in the polyamide layer. Density functional theory calculations and molecular dynamics simulations revealed the mechanisms underlying the regulation of amine monomer diffusion and gas-bubble release by carbonates and LTIP. The fabricated membrane has a smoother, ultrathin separation layer while maintaining a high permeability of 35.0 L·m⁻²·h⁻¹·bar⁻¹ (nearly doubled compared with the pristine membrane) and high Na₂SO₄ rejection of 99.5 %. This study confirms the practicality of the carbonate-modulated LTIP strategy.

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用 NaHCO3 调节低温界面聚合，实现高性能超薄纳滤膜

由于不受控制的扩散和超快聚合，传统的界面聚合（IP）在实现理想的纳滤膜（NF）结构方面遇到了巨大挑战。我们的研究在低温界面聚合（LTIP）过程中引入碳酸盐，以精确调节胺单体的扩散和聚合动力学。水相中的碳酸盐限制了胺单体的扩散，同时促进了纳米气泡的生成。进一步利用低温油相不仅能延缓聚合，还能促进聚酰胺层中泡沫纳米结构的形成。密度泛函理论计算和分子动力学模拟揭示了碳酸盐和 LTIP 对胺单体扩散和气泡释放的调节机制。制成的膜具有更平滑的超薄分离层，同时保持了 35.0 L-m-2-h-1-bar-1 的高渗透率（与原始膜相比几乎翻了一番）和 99.5% 的高 Na2SO4 阻隔率。这项研究证实了碳酸盐调制 LTIP 策略的实用性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Chemical Engineering Science 工程技术-工程：化工

CiteScore

7.50

自引率

8.50%

发文量

1025

审稿时长

50 days

期刊介绍： Chemical engineering enables the transformation of natural resources and energy into useful products for society. It draws on and applies natural sciences, mathematics and economics, and has developed fundamental engineering science that underpins the discipline. Chemical Engineering Science (CES) has been publishing papers on the fundamentals of chemical engineering since 1951. CES is the platform where the most significant advances in the discipline have ever since been published. Chemical Engineering Science has accompanied and sustained chemical engineering through its development into the vibrant and broad scientific discipline it is today.