Continuous addition kinetic elucidation: catalyst and reactant order, rate constant, and poisoning from a single experiment

Kinetic analysis of catalytic reactions is a powerful tool for mechanistic elucidation but is often challenging to perform, limiting understanding and therefore development of these reactions. Establishing order in a catalyst is usually achieved by running several reactions at different loadings, which is both time-consuming and complicated by the challenge of maintaining consistent run-to-run experimental conditions. Continuous addition kinetic elucidation (CAKE) was developed to circumvent these issues by continuously injecting a catalyst into a reaction, while monitoring reaction progress over time. For reactions that are mth order in a single yield-limiting reactant and nth order in catalyst, a plot of reactant concentration against time has a shape dependent only on the orders m and n. Therefore, fitting experimental CAKE data (using open access code or a convenient web tool) allows the reactant and catalyst orders, rate constant, and the amount of complete catalyst inhibition to be determined from a single experiment. Kinetic information obtained from CAKE experiments showed good agreement with the literature. CAKE involves continuous injection of a catalyst to determine multiple kinetic parameters, including catalyst order, from one experiment, thus reducing the workload and avoiding the pot-to-pot reproducibility issues caused by catalyst poisoning.

Automated summary

Continuous addition kinetic elucidation (CAKE) is a method to address the challenges in catalytic reactions by continuously injecting a catalyst and monitoring reaction progress, reducing workload and improving reproducibility.