Accelerated Entropic Path Sampling with a Bidirectional Generative Adversarial Network

The role of entropy in mediating the dynamic outcomes of chemical reactions remains largely unknown. To evaluate the change of entropy along post-transition state paths, we have previously developed entropic path sampling that computes configurational entropy from an ensemble of reaction trajectories. However, one major caveat of this approach lies in its high computational demand: about 2000 trajectories are needed to converge the computation of an entropic profile. Here, by leveraging a deep generative model, we developed an accelerated entropic path sampling approach that evaluates entropic profiles using merely a few hundred reaction dynamic trajectories. The new method, called bidirectional generative adversarial network-entropic path sampling, can enhance the estimation of probability density functions of molecular configurations by generating pseudo-molecular configurations that are statistically indistinguishable from the true data. The method was established using cyclopentadiene dimerization, in which we reproduced the reference entropic profiles (derived from 2480 trajectories) using merely 124 trajectories. The method was further benchmarked using three reactions with symmetric post-transition-state bifurcation, including endo-butadiene dimerization, 5-fluoro-1,3-cyclopentadiene dimerization, and 5-methyl-1,3-cyclopentadiene dimerization. The results indicate the existence of a hidden entropic intermediate, which is a dynamic species that binds to a local entropic maximum where no free energy minimum is formed.

Automated summary

The study focuses on understanding the role of entropy in chemical reactions and developing a more efficient method for computing entropic profiles. The authors utilized a deep generative model to accelerate the computation of entropy along reaction trajectories. The new approach, called bidirectional generative adversarial network-entropic path sampling, successfully reproduced reference entropic profiles using significantly fewer trajectories. The method was further validated with three reactions, revealing the presence of a hidden entropic intermediate.