Li+ Separation from Multi-Ionic Mixtures by Nanofiltration Membranes: Experiments and Modeling

WIT transactions on modelling and simulation Pub Date : 2023-09-20 DOI:10.3390/modelling4030024

Tobias Hubach, Marcel Pillath, Clemens Knaup, Stefan Schlüter, Christoph Held

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Abstract

Aqueous sources like salt lake brines and seawater are the most abundant source for lithium ions and might contribute to the growing demand for lithium for energy storage. By coupling with the increasingly relevant reverse osmosis systems, nanofiltration can provide a promising process alternative to conventional methods such as water evaporation and salt precipitation from ores or brines for this purpose. One possible model for nanofiltration is the solution-diffusion-electromigration model (SDEM). First, the model was parametrized by determining the permeances from simple electrolyte mixtures containing two salts. Then, the SDEM was used to predict the rejections of complex multi-electrolyte solutions that mimic seawater and reverse osmosis brine, without fitting additional parameters to experimental data of this complex mixture. This allowed predicting ion rejections satisfactorily. Negative rejections due to spontaneously generated electric fields in the membrane could also be qualitatively described. In summary, this SDEM modeling can provide an important contribution to the purification of Li+ from aqueous sources.

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纳滤膜从多离子混合物中分离Li+:实验与模拟

盐湖盐水和海水等水源是锂离子最丰富的来源，可能会导致锂储能需求的增长。通过与日益相关的反渗透系统相结合，纳滤可以提供一种有前途的工艺替代传统的方法，如水蒸发和从矿石或盐水中沉淀盐。一种可能的纳滤模型是溶液扩散电迁移模型(SDEM)。首先，通过测定含有两种盐的简单电解质混合物的渗透率，对模型进行了参数化。然后，使用SDEM来预测模拟海水和反渗透盐水的复杂多电解质溶液的截除率，而不需要对这种复杂混合物的实验数据拟合额外的参数。这可以令人满意地预测离子排斥。负排斥由于自发产生的电场在膜上也可以定性描述。综上所述，这种SDEM模型可以为从水源中纯化Li+提供重要贡献。

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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WIT transactions on modelling and simulation

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