Benchmarking machine-readable vectors of chemical reactions on computed activation barriers

In recent years, there has been a surge of interest in predicting computed activation barriers, to enable the acceleration of the automated exploration of reaction networks. Consequently, various predictive approaches have emerged, ranging from graph-based models to methods based on the three-dimensional structure of reactants and products. In tandem, many representations have been developed to predict experimental targets, which may hold promise for barrier prediction as well. Here, we bring together all of these efforts and benchmark various methods (Morgan fingerprints, the DRFP, the CGR representation-based Chemprop, SLATMd, B2Rl2, EquiReact and language model BERT + RXNFP) for the prediction of computed activation barriers on three diverse datasets.|We benchmark various methods for the prediction of computed activation barriers on three diverse datasets.

Benchmarking machine-readable vectors of chemical reactions on computed activation barriers

A tutorial on graph models for scheduling round-robin sports tournaments

Imaging Catalysis: Operando Investigation of the CO2 Hydrogenation Reaction Dynamics by Means of Infrared Thermography

Control Theory Concepts for Modeling Uncertainty in Enzyme Kinetics of Biochemical Networks

Imaging Catalysis: Operando Investigation of the CO2 Hydrogenation Reaction Dynamics by Means of Infrared Thermography

Control Theory Concepts for Modeling Uncertainty in Enzyme Kinetics of Biochemical Networks

A tutorial on graph models for scheduling round-robin sports tournaments