Abstract
The spatiotemporal pattern formation is studied in the catalytic carbon monoxide oxidation reaction that takes into account the diffusion processes over the Pt(110) surface, which may contain structurally different areas. These areas are formed during CO-induced transition from a reconstructed phase with $1\times2$ geometry of the overlayer to a bulk-like ($1\times1$) phase with square atomic arrangement. Despite the CO oxidation reaction being non-autocatalytic, we have shown that the analytic conditions of the existence of the Turing and the Hopf bifurcations can be satisfied in such systems. Thus, the system may lose its stability in two ways --- either through the Hopf bifurcation leading to the formation of temporal patterns in the system or through the Turing bifurcation leading to the formation of regular spatial patterns. At a simultaneous implementation of both scenarios, spatiotemporal patterns for CO and oxygen coverages are obtained in the system.
Highlights
In recent times, spatiotemporal pattern formation in spatially extended systems, such as reactiondiffusion systems, has been extensively studied [1,2,3,4]
We study the mechanisms of spatiotemporal pattern formation in the carbon monoxide oxidation reaction on the surface of Pt(110)
Despite the CO oxidation reaction being non-autocatalytic, we have shown that the analytic conditions of the existence of the Turing and the Hopf bifurcations can be satisfied at certain values of the system parameters
Summary
Spatiotemporal pattern formation in spatially extended systems, such as reactiondiffusion systems, has been extensively studied [1,2,3,4] In these systems, the concentration of one or more substances distributed in space can change under the influence of two processes: local chemical reactions in which the substances transform into each other, and diffusion which causes the substances to spread out over a surface in space. The catalytic oxidation of CO on platinum (110) is one of the most prominent examples of a reaction-diffusion system showing a variety of complex spatiotemporal patterns [5,6,7,8]. The experimental parameters were chosen such that the reaction was oscillatory and, uniform oscillations were unstable and a complex state of spiral-wave turbulence spontaneously developed
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