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Autonomous design of new chemical reactions using a variational autoencoder

Chemistry

Autonomous design of new chemical reactions using a variational autoencoder

R. Tempke and T. Musho

This groundbreaking study by Robert Tempke and Terence Musho explores the bias in current chemical reaction datasets, introducing AGoRaS, an AI model that generates over 7 million synthetic reactions from a mere 7,000, enhancing diversity and applicability in molecular research.

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~3 min • Beginner • English
Abstract
Artificial intelligence based chemistry models are a promising method of exploring chemical reaction design spaces. However, training datasets based on experimental synthesis are typically reported only for the optimal synthesis reactions. This leads to an inherited bias in the model predictions. Therefore, robust datasets that span the entirety of the solution space are necessary to remove inherited bias and permit complete training of the space. In this study, an artificial intelligence model based on a Variational AutoEncoder (VAE) has been developed and investigated to synthetically generate continuous datasets. The approach involves sampling the latent space to generate new chemical reactions. This developed technique is demonstrated by generating over 7,000,000 new reactions from a training dataset containing only 7,000 reactions. The generated reactions include molecular species that are larger and more diverse than the training set.
Publisher
Communications Chemistry
Published On
Mar 22, 2022
Authors
Robert Tempke, Terence Musho
Tags
chemical reactions
AI model
Variational AutoEncoder
synthetic dataset
molecular species
data bias
AGoRaS

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