New compact expressions for concentration-polarization of trace-ions in pressure-driven membrane processes

IF 4.9 Q1 ENGINEERING, CHEMICAL Journal of Membrane Science Letters Pub Date : 2021-12-05 DOI:10.1016/j.memlet.2021.100003
Yaeli S. Oren , Viatcheslav Freger , Oded Nir
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Abstract

Accounting for concentration-polarization (CP) is critical for modeling solute transport in membrane separation processes. In a mixed-electrolyte solution, ions' CP is affected not only by diffusion and advection but also by electromigration. Yet, the classic film model, lacking an electromigration term, is frequently used for modeling ion CP. Often, ion CP is altogether neglected to reduce the computational load. Here, we study the CP of trace ions in a dominant salt solution, a case relevant for many reverse-osmosis and nanofiltration processes. First, we revisit the solution-diffusion-electromigration-film theory to obtain an analytical solution for the CP and membrane-transport of trace-ions in a dominant salt solution. Secondly, we consider limiting conditions relevant to reverse-osmosis and nanofiltration, from which we derive two compact equations that emerge as a seamless extension to the classic film theory. These equations can be used to account for the effect of electromigration on CP with minimal effort. Thirdly, we use our theory to quantify the effect of electromigration on ion CP in different dominant salt solutions. Finally, by analyzing two environmental membrane processes, we demonstrate how our theory deviates from the conventional one and quantify the implications on membrane scaling potential and the transport of ionic contaminants.

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压力驱动膜过程中痕量离子浓度-极化的新紧凑表达式
考虑浓度极化(CP)是模拟膜分离过程中溶质输运的关键。在混合电解质溶液中,离子的CP不仅受到扩散和平流的影响,还受到电迁移的影响。然而,缺乏电迁移项的经典薄膜模型经常用于离子CP的建模。通常,为了减少计算负荷,离子CP被完全忽略。在这里,我们研究了微量离子在显性盐溶液中的CP,这是一个与许多反渗透和纳滤过程相关的案例。首先,我们重新审视了溶液-扩散-电迁移-膜理论,以获得显性盐溶液中微量离子的CP和膜输运的解析解。其次,我们考虑了与反渗透和纳滤相关的限制条件,从中我们推导出两个紧凑的方程,作为经典薄膜理论的无缝扩展。这些方程可以用最小的努力来解释电迁移对CP的影响。第三,我们用我们的理论量化了不同优势盐溶液中电迁移对离子CP的影响。最后,通过分析两个环境膜过程,我们证明了我们的理论是如何偏离传统的,并量化了对膜结垢势和离子污染物运输的影响。
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