A practical approach to the sensitivity analysis for kinetic Monte Carlo simulation of heterogeneous catalysis

TL;DR

This paper introduces an efficient three-stage sensitivity analysis method for kinetic Monte Carlo simulations of heterogeneous catalysis, enabling better atomic-level catalyst design with reduced computational effort.

Contribution

It presents a novel, robust approach combining Fisher Information Matrix, linear response theory, and coupled finite differences for sensitivity analysis in stochastic microkinetic models.

Findings

Significant computational savings demonstrated.

Effective sensitivity evaluation near phase transitions.

Applicable to complex surface reaction models.

Abstract

Lattice kinetic Monte Carlo simulations have become a vital tool for predictive quality atomistic understanding of complex surface chemical reaction kinetics over a wide range of reaction conditions. In order to expand their practical value in terms of giving guidelines for atomic level design of catalytic systems, it is very desirable to readily evaluate a sensitivity analysis for a given model. The result of such a sensitivity analysis quantitatively expresses the dependency of the turnover frequency, being the main output variable, on the rate constants entering the model. In the past the application of sensitivity analysis, such as Degree of Rate Control, has been hampered by its exuberant computational effort required to accurately sample numerical derivatives of a property that is obtained from a stochastic simulation method. In this study we present an efficient and robust three stage approach that is capable of reliably evaluating the sensitivity measures for stiff microkinetic models as we demonstrate using CO oxidation on RuO2(110) as a prototypical reaction. In a first step, we utilize the Fisher Information Matrix for filtering out elementary processes which only yield negligible sensitivity. Then we employ an estimator based on linear response theory for calculating the sensitivity measure for non-critical conditions which covers the majority of cases. Finally we adopt a method for sampling coupled finite differences for evaluating the sensitivity measure of lattice based models. This allows efficient evaluation even in critical regions near a second order phase transition that are hitherto difficult to control. The combined approach leads to significant computational savings over straightforward numerical derivatives and should aid in accelerating the nano scale design of heterogeneous catalysts.