Abstract
Over the past 35 years rate oscillations and chemical wave patterns have been extensively studied on metal surfaces, while little is known about the dynamics of catalytic oxide surfaces under reaction conditions. Here we report on the behavior of ultrathin V oxide layers epitaxially grown on Rh(111) and Rh(110) single crystal surfaces during catalytic methanol oxidation. We use photoemission electron microscopy and low-energy electron microscopy to study the surface dynamics in the 10−6 to 10−2 mbar range. On VOx/Rh(111) we find a ripening mechanism in which VOx islands of macroscopic size move toward each other and coalesce under reaction conditions. A polymerization/depolymerization mechanism of VOx that is sensitive to gradients in the oxygen coverage explains this behavior. The existence of a substructure in VOx islands gives rise to an instability, in which a VOx island shrinks and expands around a critical radius in an oscillatory manner. At 10−2 mbar the VOx islands are no longer stable but they disintegrate, leading to turbulent redistribution dynamics of VOx. On the more open and thermodynamically less stable Rh(110) surface the behavior of VOx is much more complex than on Rh(111), as V can also populate subsurface sites. At low V coverage, one finds traveling interface pulses in the bistable range. A state-dependent anisotropy of the surface is presumably responsible for intriguing chemical wave patterns: wave fragments traveling along certain crystallographic directions, and coexisting different front geometries in the range of dynamic bistability. Annealing to 1000 K causes the formation of macroscopic VOx islands. Under more reducing conditions dendritic growth of a VOx overlayer is observed.
Highlights
Chemical waves and kinetic oscillations on catalytic surfaces have been studied starting from about 1980 with the vast majority focusing on reactions on metal surfaces (Ertl, 1991; Imbihl and Ertl, 1995; Imbihl, 2005)
By generating an island structure at 10−4 mbar in a preparation chamber followed by transfer to the LEEM chamber, FIGURE 14 | PEEM images showing traveling wave fragments propagating on VOx islands during methanol oxidation on VOx/Rh(110). (A) Nucleation of wave fragments at the borders of the VOx islands
Studying catalytic reactions on VOx/Rh(111) and VOx/Rh(110), the range of non-linear phenomena in catalysis has been expanded from metal surfaces to oxidic systems
Summary
Chemical waves and kinetic oscillations on catalytic surfaces have been studied starting from about 1980 with the vast majority focusing on reactions on metal surfaces (Ertl, 1991; Imbihl and Ertl, 1995; Imbihl, 2005). O-concentration profiles obtained with in situ μXPS during the NO + NH3 reaction showed that the interface VOx covered surface/bare metal surface is rather broad and exhibits no steep gradient, quite in contrast to the oxidation with O2 where gradients at the interface are steep (von Boehn, 2020) This latter observation of a broad interface can be taken as evidence for a reduced line tension at the interface compared to the oxidation reaction with O2. The conclusion that the line tension VOx/metal surface is reduced in the case of NO points in this direction, but quantitative data are required in order to reach definite answers
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