Metal–organic framework clustering through the lens of transfer learning†

IF 3.2 3区工程技术 Q2 CHEMISTRY, PHYSICAL

Molecular Systems Design & Engineering Pub Date : 2023-04-11 DOI:10.1039/D3ME00016H

Gregory M. Cooper and Yamil J. Colón

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Abstract

Metal–organic frameworks (MOFs) are promising materials with various applications, and machine learning (ML) techniques can enable their design and understanding of structure–property relationships. In this paper, we use machine learning (ML) to cluster the MOFs using two different approaches. For the first set of clusters, we decompose the data using the textural properties and cluster the resulting components. We separately cluster the MOF space with respect to their topology. The feature data from each of the clusters were then fed into separate neural networks (NNs) for direct learning on an adsorption task (methane or hydrogen). The resulting NNs were then used in transfer learning (TL) where only the last NN layer was retrained. The results show significant differences in TL performance based on which cluster is chosen for direct learning. We find TL performance depends on the Euclidean distance in the decomposed feature space between the clusters involved in the direct and TL. Similar results were found when TL was performed simultaneously across both types of clusters and adsorption tasks. We note that methane adsorption was a better source task than hydrogen adsorption. Overall, the approach was able to identify MOFs with the most transferable information, leading to valuable insights and a more comprehensive understanding of the MOF landscape. This highlights the method's potential to generate a deeper understanding of complex systems and provides an opportunity for its application in alternative datasets.

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迁移学习视角下的金属-有机框架聚类研究

金属有机框架(mof)是具有各种应用前景的材料，机器学习(ML)技术可以使其设计和理解结构-性质关系。在本文中，我们使用机器学习(ML)使用两种不同的方法对mof进行聚类。对于第一组聚类，我们使用纹理属性分解数据并将结果组件聚类。我们分别对MOF空间的拓扑结构进行聚类。然后将每个簇的特征数据输入到单独的神经网络(NNs)中，用于直接学习吸附任务(甲烷或氢气)。然后将得到的神经网络用于迁移学习(TL)，其中只对最后一层神经网络进行再训练。结果表明，基于选择哪种聚类进行直接学习，在语言学习性能上存在显著差异。我们发现TL的性能取决于直接和TL所涉及的簇之间在分解特征空间中的欧几里得距离。当TL同时在两种类型的簇和吸附任务中进行时，发现了类似的结果。我们注意到甲烷吸附是比氢吸附更好的源任务。总体而言，该方法能够识别具有最可转移信息的MOF，从而获得有价值的见解，并对MOF景观有更全面的了解。这突出了该方法对复杂系统产生更深层次理解的潜力，并为其在替代数据集中的应用提供了机会。

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来源期刊

Molecular Systems Design & Engineering Engineering-Biomedical Engineering

CiteScore

6.40

自引率

2.80%

发文量

144

期刊介绍： Molecular Systems Design & Engineering provides a hub for cutting-edge research into how understanding of molecular properties, behaviour and interactions can be used to design and assemble better materials, systems, and processes to achieve specific functions. These may have applications of technological significance and help address global challenges.