Extensive Attention Mechanisms in Graph Neural Networks for Materials Discovery

Guojing Cong, Talia Ben-Naim, Victor Fung, Anshul Gupta, R. Neumann, Mathias Steiner
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引用次数: 1

Abstract

We present our research where attention mechanism is extensively applied to various aspects of graph neural net- works for predicting materials properties. As a result, surrogate models can not only replace costly simulations for materials screening but also formulate hypotheses and insights to guide further design exploration. We predict formation energy of the Materials Project and gas adsorption of crystalline adsorbents, and demonstrate the superior performance of our graph neural networks. Moreover, attention reveals important substructures that the machine learning models deem important for a material to achieve desired target properties. Our model is based solely on standard structural input files containing atomistic descriptions of the adsorbent material candidates. We construct novel methodological extensions to match the prediction accuracy of state-of-the-art models some of which were built with hundreds of features at much higher computational cost. We show that sophisticated neural networks can obviate the need for elaborate feature engineering. Our approach can be more broadly applied to optimize gas capture processes at industrial scale.
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图神经网络在材料发现中的广泛注意机制
我们介绍了我们的研究,其中注意机制被广泛应用于图神经网络预测材料性能的各个方面。因此,替代模型不仅可以取代昂贵的材料筛选模拟,还可以制定假设和见解,以指导进一步的设计探索。我们预测了材料项目的形成能和晶体吸附剂的气体吸附,并证明了我们的图神经网络的优越性能。此外,注意力揭示了重要的子结构,机器学习模型认为这些子结构对于材料实现所需的目标特性很重要。我们的模型完全基于包含吸附剂候选材料的原子描述的标准结构输入文件。我们构建了新的方法扩展,以匹配最先进的模型的预测精度,其中一些模型是用数百个特征构建的,计算成本要高得多。我们表明,复杂的神经网络可以避免复杂的特征工程的需要。我们的方法可以更广泛地应用于优化工业规模的气体捕获过程。
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