Abstract
Surface chemical composition of bimetallic catalysts can differ from the bulk composition because of the segregation of the alloy components. Thus, it is very useful to know how the different components are arranged on the surface of catalysts to gain a fundamental understanding of the catalysis occurring on bimetallic surfaces. First-principles density functional theory (DFT) calculations can provide deeper insight into the surface segregation behavior and help understand the surface composition on bimetallic surfaces. However, the DFT calculations are computationally demanding and require large computing platforms. In this regard, statistical/machine learning methods provide a quick and alternative approach to study materials properties. Here, we trained previously reported surface segregation energies on low index surfaces of bimetallic catalysts using various linear and non-linear statistical methods to find a correlation between surface segregation energies and elemental properties. The results revealed that the surface segregation energies on low index bimetallic surfaces can be predicted using fundamental elemental properties.
Highlights
Transition metals (TM) catalyze many catalytic and electrocatalytic reactions [1,2,3,4,5,6,7]
Results obtained from the various statistical models used in this study demonstrated that the surface segregation energies of bimetallic alloys can be predicted using simple non-linear regression methods
The surface segregation energies on bimetallic face centered cubic (FCC) (111) surfaces were modeled using OLS, PLS, support vector regression (SVR), GPR, gradient boosting regression (GBR) and KRR methods
Summary
Transition metals (TM) catalyze many catalytic and electrocatalytic reactions [1,2,3,4,5,6,7]. The catalytic activity and selectivity of transition metal-based catalysts can be altered significantly by adding a second/guest metal in host metals [6,8,9,10,11,12]. The addition of the second/guest metal in host metal could result in the formation of an ordered bimetallic alloy with a well-defined crystal structure. It has been shown over the years for many reactions that bimetallic alloy catalysts show superior activity compared to monometallic catalysts [6,12,13,14]. Alloying has been found to be an effective way to improve the activity of TM based catalysts in heterogeneous catalysis [6,12,16,17,18]
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