E. Evdochenko , A. Kalde , J. di Ronco , K. Albert , J. Kamp , M. Wessling
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引用次数: 0
Abstract
Polyelectrolyte-based nanofiltration membranes are obtained through a layer-by-layer sequential deposition of oppositely charged polyelectrolytes (PEs) onto a porous support structure. The resulting polyelectrolyte membrane offers tailored salt rejections for nanofiltration applications. However, little is known about the exact location of the deposited PEs on top or inside a membrane pore. Also, scarce information is available on the contribution of the different potential PE locations that affect the salt rejection of the overall membrane. Hence, research challenges, such as the influence of (a) an adsorbed PE layer inside the support membrane or (b) the bridging of the original pores and the position of the bridging layer, can only be unraveled through rigorous simulations. We present a significant extension of our previously published model into a two-dimensional modeling framework pEnPEnS (pressure p driven transport through n electrolyte layers En, n polyelectrolyte layers PEn, and the support structure S) capable of addressing the selective layer additionally formed on the walls of the support capillary structure. The model solves a set of two-dimensional nonlinear Extended Nernst-Planck-Poisson and Navier-Stokes-Brinkman equations, enabling the prediction of ionic rejections from the top coating, wall coating, and a PE bridging forming inside the capillary. The proposed model framework systematically identifies and quantifies the influence of the capillary coating beneath the top layer on NaCl rejection and addresses the challenge of improving rejection rates. The model reveals that PEs deposited inside the support structure contribute significantly to NaCl rejection. It enables the predictions of differences in the rejection rates depending on the location of the PE coating, the diameter of the support capillary, and the transmembrane pressure. The model gives insight into PE bridging forming inside the support capillary and explains how its position and fixed charge density change ion rejection rates. As such, the model unravels insightful details on the rejection characteristics of coated capillaries, making it a powerful tool for designing polyelectrolyte membranes.
基于聚电解质的纳滤膜是通过在多孔支撑结构上逐层连续沉积带相反电荷的聚电解质(PE)而获得的。由此产生的聚电解质膜可为纳滤应用提供量身定制的拒盐能力。然而,人们对沉积在膜孔顶部或内部的聚电解质的确切位置知之甚少。此外,关于不同潜在 PE 位置对整个膜的盐排斥作用的影响,也鲜有资料。因此,只有通过严格的模拟,才能解开研究难题,如(a)吸附在支撑膜内的 PE 层或(b)原始孔隙的桥接和桥接层位置的影响。我们将之前发表的模型大幅扩展为二维建模框架 pEnPEnS(压力 p 驱动通过 n 个电解质层 En、n 个聚电解质层 PEn 和支撑结构 S 的传输),能够解决在支撑毛细管结构壁上额外形成的选择层问题。该模型求解了一组二维非线性扩展 Nernst-Planck-Poisson 和 Navier-Stokes-Brinkman 方程,从而能够预测毛细管内部形成的顶涂层、壁涂层和 PE 桥接层的离子排斥情况。所提出的模型框架系统地确定并量化了顶层下毛细管涂层对 NaCl 排阻的影响,并解决了提高排阻率的难题。该模型揭示了沉积在支撑结构内部的聚乙烯对 NaCl 排斥的重要作用。根据聚乙烯涂层的位置、支撑毛细管的直径和跨膜压力的不同,该模型可以预测排斥率的差异。该模型深入揭示了支撑毛细管内形成的聚乙烯桥接,并解释了其位置和固定电荷密度如何改变离子剔除率。因此,该模型揭示了涂层毛细管排斥特性的深刻细节,是设计聚电解质膜的有力工具。
期刊介绍:
Desalination is a scholarly journal that focuses on the field of desalination materials, processes, and associated technologies. It encompasses a wide range of disciplines and aims to publish exceptional papers in this area.
The journal invites submissions that explicitly revolve around water desalting and its applications to various sources such as seawater, groundwater, and wastewater. It particularly encourages research on diverse desalination methods including thermal, membrane, sorption, and hybrid processes.
By providing a platform for innovative studies, Desalination aims to advance the understanding and development of desalination technologies, promoting sustainable solutions for water scarcity challenges.