可解释的机器学习用于揭示聚酰亚胺有机溶剂纳滤膜中的溶剂效应

Gergo Ignacz, Nawader Alqadhi, Gyorgy Szekely
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引用次数: 13

摘要

目前,了解溶剂对有机溶剂纳滤的影响取决于从小型数据集获得的结果,这减缓了该技术的工业实施。我们提出了一项深入的研究,以确定和统一溶剂参数对溶质截留率的影响。为此,我们在中等通量横流纳滤系统中使用聚酰亚胺膜测量了407种溶质在11种常见和绿色溶剂中的截留率。基于大数据集,我们通过实验验证了溶剂结构的渗透率和电子效应(希尔德布兰德参数、电拓扑描述符和LogP)对平均溶质截留率有很大影响。我们进一步确定了影响溶质截留率的最重要的溶剂参数。我们的数据集用于构建和测试图神经网络,以预测溶质的排斥。结果与内部和文献数据进行了严格的测试,并证明了良好的通用性和稳健性。我们的模型显示,内部和文献测试集的均方根误差分别为0.124(86.4%R2)和0.123(71.4 R2)。可解释的人工智能有助于理解和可视化原子和官能团改变排斥反应的潜在影响。
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Explainable machine learning for unraveling solvent effects in polyimide organic solvent nanofiltration membranes

Understanding the effects of solvents on organic solvent nanofiltration currently depends on results obtained from small datasets, which slows down the industrial implementation of this technology. We present an in-depth study to identify and unify the effects of solvent parameters on solute rejection. For this purpose, we measured the rejection of 407 solutes in 11 common and green solvents using a polyimide membrane in a medium-throughput cross-flow nanofiltration system. Based on the large dataset, we experimentally verify that permeance and electronic effects of the solvent structure (Hildebrand parameters, electrotopological descriptors, and LogP) have strong impact on the average solute rejection. We furthermore identify the most important solvent parameters affecting solute rejection. Our dataset was used to build and test a graph neural network to predict the rejection of solutes. The results were rigorously tested against both internal and literature data, and demonstrated good generalization and robustness. Our model showed 0.124 (86.4% R2) and 0.123 (71.4 R2) root mean squared error for the internal and literature test sets, respectively. Explainable artificial intelligence helps understand and visualize the underlying effects of atoms and functional groups altering the rejection.

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来源期刊
CiteScore
8.50
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0.00%
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