AI for Interpretable Chemistry: Predicting Radical Mechanistic Pathways via Contrastive Learning

• URL: http://arxiv.org/abs/2311.01118v1
• Date: Thu, 2 Nov 2023 09:47:27 GMT
• Title: AI for Interpretable Chemistry: Predicting Radical Mechanistic Pathways via Contrastive Learning
• Authors: Mohammadamin Tavakoli, Yin Ting T.Chiu, Alexander Shmakov, Ann Marie Carlton, David Van Vranken, Pierre Baldi
• Abstract summary: RMechRP is a new deep learning-based reaction predictor system. We develop and train models using RMechDB, a public database of radical reactions. Our results demonstrate the effectiveness of RMechRP in providing accurate and interpretable predictions.
• Score: 45.379791270351184
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Deep learning-based reaction predictors have undergone significant architectural evolution. However, their reliance on reactions from the US Patent Office results in a lack of interpretable predictions and limited generalization capability to other chemistry domains, such as radical and atmospheric chemistry. To address these challenges, we introduce a new reaction predictor system, RMechRP, that leverages contrastive learning in conjunction with mechanistic pathways, the most interpretable representation of chemical reactions. Specifically designed for radical reactions, RMechRP provides different levels of interpretation of chemical reactions. We develop and train multiple deep-learning models using RMechDB, a public database of radical reactions, to establish the first benchmark for predicting radical reactions. Our results demonstrate the effectiveness of RMechRP in providing accurate and interpretable predictions of radical reactions, and its potential for various applications in atmospheric chemistry.

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