Automated Mechanism Generation Using Linear Scaling Relationships and Sensitivity Analyses Applied to Catalytic Partial Oxidation of Methane

Emily J. Mazeau, Priyanka Satpute, Katrín Blöndal, C. Franklin Goldsmith, Richard H. West

Research output: Contribution to journalArticlepeer-review

27 Scopus citations

Abstract

Kinetic parameters for surface reactions can be predicted using a combination of density functional theory calculations, scaling relations, and machine learning algorithms; however, construction of microkinetic models still requires a knowledge of all the possible, or at least reasonable, reaction pathways. The recently developed reaction mechanism generator (RMG) for heterogeneous catalysis, now included in RMG version 3.0, is built upon well-established, open-source software that can provide detailed reaction mechanisms from user-supplied initial conditions without makinga prioriassumptions. RMG is now able to estimate adsorbate thermochemistry and construct detailed microkinetic models on a range of hypothetical metal surfaces using linear scaling relationships. These relationships are a simple, computationally efficient way to estimate adsorption energies by scaling the energy of a calculated surface species on one metal to any other metal. By conducting simulations with sensitivity analyses, users can not only determine the rate-limiting step on each surface by plotting a “volcano surface” for the degree of rate control of each reaction as a function of elemental binding energies but also screen novel catalysts for desirable properties. We investigated the catalytic partial oxidation of methane to demonstrate the utility of this new tool and determined that an inlet gas C/O ratio of 0.8 on a catalyst with carbon and oxygen binding energies of −6.75 and −5.0 eV, respectively, yields the highest amount of synthesis gas. Sensitivity analyses show that while the dissociative adsorption of O2has the highest degree of rate control, the interactions between individual reactions and reactor conditions are complex, which result in a dynamic rate-limiting step across differing metals.

Original languageEnglish
Pages (from-to)7114-7125
Number of pages12
JournalACS Catalysis
Volume11
Issue number12
DOIs
StatePublished - Jun 18 2021
Externally publishedYes

Funding

The authors thank Nathan Harms, Sai Krishna Sirumalla, David Medina-Cruz, Chris Blais, David Farina Jr., Nirvana Delgado Otalvaro, and Bjarne Kreitz for helpful suggestions. This work was supported by the U.S. Department of Energy, Office of Science, Basic Energy Sciences, under Award #0000232253, as part of the Computational Chemical Sciences Program. The computational work was performed in part using computing resources from the following: National Energy Research Scientific Computing Center (NERSC) operated by Lawrence Berkeley National Laboratory, Discovery cluster supported by Northeastern University’s Research Computing team, and Argonne Leadership Computing Facility operated by the Argonne National Laboratory.

Keywords

  • catalytic partial oxidation
  • kinetics
  • linear scaling
  • reaction mechanism generation
  • sensitivity analyses

Fingerprint

Dive into the research topics of 'Automated Mechanism Generation Using Linear Scaling Relationships and Sensitivity Analyses Applied to Catalytic Partial Oxidation of Methane'. Together they form a unique fingerprint.

Cite this