AI-assisted modeling of capillary-driven droplet dynamics

Data-Centric Engineering Pub Date : 2023-01-01 DOI:10.1017/dce.2023.19

Andreas D. Demou, Nikos Savva

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Abstract

Abstract In this study, we present and assess data-driven approaches for modeling contact line dynamics, using droplet transport on chemically heterogeneous surfaces as a model system. Ground-truth data for training and validation are generated based on long-wave models that are applicable for slow droplet motion with small contact angles, which are known to accurately reproduce the dynamics with minimal computing resources compared to high-fidelity direct numerical simulations. The data-driven models are based on the Fourier neural operator (FNO) and are developed following two different approaches. The first deploys the data-driven method as an iterative neural network architecture, which predicts the future state of the contact line based on a number of previous states. The second approach corrects the time derivative of the contact line by augmenting its low-order asymptotic approximation with a data-driven counterpart, evolving the resulting system using standard time integration methods. The performance of each approach is evaluated in terms of accuracy and generalizability, concluding that the latter approach, although not originally explored within the original contribution on the FNO, outperforms the former.

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人工智能辅助毛细管驱动液滴动力学建模

在这项研究中，我们提出并评估了数据驱动的接触线动力学建模方法，使用化学非均质表面上的液滴传输作为模型系统。用于训练和验证的真实数据是基于长波模型生成的，该模型适用于具有小接触角的慢速液滴运动，与高保真度的直接数值模拟相比，已知长波模型可以用最少的计算资源准确地再现动力学。数据驱动模型基于傅里叶神经算子(FNO)，并遵循两种不同的方法开发。第一种方法将数据驱动方法部署为迭代神经网络架构，该架构基于许多先前的状态来预测接触线的未来状态。第二种方法通过用数据驱动的对应项增加接触线的低阶渐近近似来校正接触线的时间导数，并使用标准时间积分方法改进得到的系统。每一种方法的性能都是根据准确性和普遍性来评估的，结论是后一种方法，尽管最初没有在FNO的原始贡献中进行探索，但优于前者。

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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Data-Centric Engineering

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