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Abstract
Zeolite synthesis frequently relies on organic structure-directing agents (OS- DAs), but the process of identifying the best OSDA to synthesize a given zeolite remains difficult. We use previously gathered binding energy data, in additional to the formation energies of the siliceous zeolite frameworks and approximate binding entropies of OSDAs to develop new descriptors to improve predictions based on known OSDA-zeolite pairs in the litera- ture. Our earlier work used templating energy (ET ) to rank the most likely OSDA-zeolite pairs to be produced from synthesis. Using literature recall area-under-the-curve (AUC) as a performance metric, we find that comput- ing energies associated with the net transformation that occurs during zeo- lite synthesis (the sum of the formation energy of the zeolite framework and the OSDA binding energy) provides a modest improvement over ET when predicting the zeolite phase that a given OSDA produces, from 67.1% aver- age literature recall to 69.1%, but slightly worsens predictions for the best OSDA for a given zeolite framework, from 67.7% to 64.9%. We then use machine learning symbolic regression to develop a new descriptor, which we call αT , that slightly improves upon ET for predicting an OSDA for a given framework, with an average literature recall of 68.2%. While zeolite synthesis remains difficult to predict a priori, the approaches used in this work provide one option for improving these predictions.
