Multimodal Language and Graph Learning of Adsorption Configuration in Catalysis

Adsorption energy, a reactivity descriptor, should be accurately assessed for efficient catalyst screening. This evaluation requires determining the lowest energy across various adsorption configurations on the catalytic surface. While graph neural networks (GNNs) have gained popularity as a machine learning approach for computing the energy of catalyst systems, they rely heavily on atomic spatial coordinates and often lack clarity in their interpretations. Recent advancements in language models have broadened their applicability to predicting catalytic properties, allowing us to bypass the complexities of graph representation. These models are adept at handling textual data, making it possible to incorporate observable features in a human-readable format. However, language models encounter challenges in accurately predicting the energy of adsorption configurations, typically showing a high mean absolute error (MAE) of about 0.71 eV. Our study addresses this limitation by introducing a self-supervised multi-modal learning approach, termed graph-assisted pretraining. This method significantly reduces the MAE to 0.35 eV through a combination of data augmentation, achieving comparable accuracy with DimeNet++ while using 0.4% of its training data size. Furthermore, the Transformer encoder at the core of the language model can provide insights into the feature focus through its attention scores. This analysis shows that our multimodal training effectively redirects the model's attention toward relevant adsorption configurations from adsorbate-related features, enhancing prediction accuracy and interpretability.