To address surface reaction network complexity using scaling relations machine learning and DFT calculations
Interface (United States) · Stanford University · +2 more institutions
Abstract
Surface reaction networks involving hydrocarbons exhibit enormous complexity with thousands of species and reactions for all but the very simplest of chemistries. We present a framework for optimization under uncertainty for heterogeneous catalysis reaction networks using surrogate models that are trained on the fly. The surrogate model is constructed by teaching a Gaussian process adsorption energies based on group additivity fingerprints, combined with transition-state scaling relations and a simple classifier for determining the rate-limiting step. The surrogate model is iteratively used to predict the most important reaction step to be calculated explicitly with computationally demanding electronic…
Citation impact
- FWCI
- 22.99
- Percentile
- 100%
- References
- 24
Authors
4Topics & keywords
- Density functional theory
- Surrogate model
- Computer science
- Scaling
- Gaussian process
- Gaussian
- Reaction rate
- Reaction mechanism