期刊
ACS CATALYSIS
卷 11, 期 12, 页码 7114-7125出版社
AMER CHEMICAL SOC
DOI: 10.1021/acscatal.0c04100
关键词
reaction mechanism generation; sensitivity analyses; linear scaling; catalytic partial oxidation; kinetics
资金
- U.S. Department of Energy, Office of Science, Basic Energy Sciences [0000232253]
The study explores the construction of microkinetic models using a reaction mechanism generator, which allows for the estimation of adsorbate thermochemistry and the construction of detailed models on various metal surfaces. By conducting sensitivity analyses, users can determine the rate-limiting step on each surface and screen novel catalysts with desirable properties.
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 making a priori assumptions. 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 O-2 has 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.
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