Neural Network Predicts Ion Concentration Profiles under Nanoconfinement

The Journal of chemical physics Pub Date : 2023-04-10 DOI:10.48550/arXiv.2304.04896

Zhonglin Cao, Yuyang Wang, Cooper Lorsung, A. Farimani

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Abstract

Modeling the ion concentration profile in nanochannel plays an important role in understanding the electrical double layer and electro-osmotic flow. Due to the non-negligible surface interaction and the effect of discrete solvent molecules, molecular dynamics (MD) simulation is often used as an essential tool to study the behavior of ions under nanoconfinement. Despite the accuracy of MD simulation in modeling nanoconfinement systems, it is computationally expensive. In this work, we propose neural network to predict ion concentration profiles in nanochannels with different configurations, including channel widths, ion molarity, and ion types. By modeling the ion concentration profile as a probability distribution, our neural network can serve as a much faster surrogate model for MD simulation with high accuracy. We further demonstrate the superior prediction accuracy of neural network over XGBoost. Finally, we demonstrated that neural network is flexible in predicting ion concentration profiles with different bin sizes. Overall, our deep learning model is a fast, flexible, and accurate surrogate model to predict ion concentration profiles in nanoconfinement.

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神经网络预测纳米约束下离子浓度分布

模拟纳米通道中的离子浓度分布对于理解电双层和电渗透流动具有重要意义。由于不可忽略的表面相互作用和离散溶剂分子的影响，分子动力学(MD)模拟经常被用作研究纳米约束下离子行为的重要工具。尽管MD模拟在纳米约束系统建模中具有准确性，但它的计算成本很高。在这项工作中，我们提出了神经网络来预测不同配置的纳米通道中的离子浓度分布，包括通道宽度、离子摩尔浓度和离子类型。通过将离子浓度分布建模为概率分布，我们的神经网络可以作为一个更快的替代模型来进行MD模拟，并且具有较高的精度。我们进一步证明了神经网络在XGBoost上优越的预测精度。最后，我们证明了神经网络在预测不同容器尺寸的离子浓度分布方面是灵活的。总的来说，我们的深度学习模型是一个快速、灵活、准确的替代模型，可以预测纳米约束下的离子浓度分布。

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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The Journal of chemical physics

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