It is well documented that different surface structures of catalytically active metals may exhibit different catalytic properties. This is typically examined by comparing the catalytic activities and/or selectivities of various well-defined smooth and stepped/kinked single crystal surfaces. Here we report the direct observation of the heterogeneity of active polycrystalline surfaces under reaction conditions, which is manifested by multifrequential oscillations during hydrogen oxidation over rhodium, imaged in situ by photoemission electron microscopy. Each specific surface structure, i.e. the crystallographically different µm-sized domains of rhodium, exhibits an individual spiral pattern and oscillation frequency, despite the global diffusional coupling of the surface reaction. This reaction behavior is attributed to the ability of stepped surfaces of high-Miller-index domains to facilitate the formation of subsurface oxygen, serving as feedback mechanism of the observed oscillations. The current experimental findings, backed by microkinetic modeling, may open an alternative approach towards addressing the structure-sensitivity of heterogeneous surfaces.
An improved methodology of the Zr specimen preparation was developed which allows fabrication of stable Zr nanotips suitable for FIM and AP applications. Initial oxidation of the Zr surface was studied on a Zr nanotip by FIM and on a polycrystalline Zr foil by XPS, both at low oxygen pressure (10−8–10−7 mbar). The XPS data reveal that in a first, fast stage of oxidation, a Zr suboxide interlayer is formed which contains three suboxide components (Zr+1, Zr+2 and Zr+3) and is located between the Zr surface and a stoichiometric ZrO2 overlayer that grows in a second, slow oxidation stage. The sole suboxide layer has been observed for the first time at very early states of the oxidation (oxygen exposure ≤4 L). The Ne+ FIM observations are in accord with a two stage process of Zr oxide formation.
Multifrequential
oscillating spatiotemporal patterns in the catalytic
hydrogen oxidation on rhodium have been observed in situ in the 10–6 mbar pressure range using photoemission electron
microscopy. The effect is manifested by periodic chemical waves, which
travel over the polycrystalline Rh surface and change their oscillation
frequency while crossing boundaries between different Rh(hkl) domains. Each crystallographically specific μm-sized Rh(hkl) domain exhibits an individual wave pattern and oscillation
frequency, despite the global diffusional coupling of the surface
reaction, altogether creating a structure library. This unique reaction
behavior is attributed to the ability of stepped surfaces of high-Miller-index
domains to facilitate the formation of subsurface oxygen, serving
as a feedback mechanism of kinetic oscillations. Formation of a network
of subsurface oxygen as a result of colliding reaction fronts was
observed in situ. Microkinetic model analysis was used to rationalize
the observed effects and to reveal the relation between the barriers
for surface oxidation and oscillation frequency. Structural limits
of the oscillations, the existence range of oscillations, as well
as the effect of varying hydrogen pressure are demonstrated.
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