Oxide-supported precious metal nanoparticles are widely used industrial catalysts. Due to expense and rarity, developing synthetic protocols that reduce precious metal nanoparticle size and stabilize dispersed species is essential. Supported atomically dispersed, single precious metal atoms represent the most efficient metal utilization geometry, although debate regarding the catalytic activity of supported single precious atom species has arisen from difficulty in synthesizing homogeneous and stable single atom dispersions, and a lack of site-specific characterization approaches. We propose a catalyst architecture and characterization approach to overcome these limitations, by depositing ∼1 precious metal atom per support particle and characterizing structures by correlating scanning transmission electron microscopy imaging and CO probe molecule infrared spectroscopy. This is demonstrated for Pt supported on anatase TiO. In these structures, isolated Pt atoms, Pt, remain stable through various conditions, and spectroscopic evidence suggests Pt species exist in homogeneous local environments. Comparing Pt to ∼1 nm preoxidized (Pt) and prereduced (Pt) Pt clusters on TiO, we identify unique spectroscopic signatures of CO bound to each site and find CO adsorption energy is ordered: Pt ≪ Pt < Pt. Pt species exhibited a 2-fold greater turnover frequency for CO oxidation than 1 nm Pt clusters but share an identical reaction mechanism. We propose the active catalytic sites are cationic interfacial Pt atoms bonded to TiO and that Pt exhibits optimal reactivity because every atom is exposed for catalysis and forms an interfacial site with TiO. This approach should be generally useful for studying the behavior of supported precious metal atoms.
Understanding the structures of catalysts under realistic conditions with atomic precision is crucial to design better materials for challenging transformations. Under reducing conditions, certain reducible supports migrate onto supported metallic particles and create strong metal-support states that drastically change the reactivity of the systems. The details of this process are still unclear and preclude its thorough exploitation. Here, we report an atomic description of a palladium/titania (Pd/TiO2) system by combining state-of-the-art in situ transmission electron microscopy and density functional theory (DFT) calculations with structurally defined materials, in which we visualize the formation of the overlayers at the atomic scale under atmospheric pressure and high temperature. We show that an amorphous reduced titania layer is formed at low temperatures, and that crystallization of the layer into either mono- or bilayer structures is dictated by the reaction environment and predicted by theory. Furthermore, it occurs in combination with a dramatic reshaping of the metallic surface facets.
Atomic-scale insights into how supported metal nanoparticles catalyze chemical reactions are critical for the optimization of chemical conversion processes. It is well-known that different geometric configurations of surface atoms on supported metal nanoparticles have different catalytic reactivity and that the adsorption of reactive species can cause reconstruction of metal surfaces. Thus, characterizing metallic surface structures under reaction conditions at atomic scale is critical for understanding reactivity. Elucidation of such insights on high surface area oxide supported metal nanoparticles has been limited by less than atomic resolution typically achieved by environmental transmission electron microscopy (TEM) when operated under realistic conditions and a lack of correlated experimental measurements providing quantitative information about the distribution of exposed surface atoms under relevant reaction conditions. We overcome these limitations by correlating density functional theory predictions of adsorbate-induced surface reconstruction visually with atom-resolved imaging by in situ TEM and quantitatively with sample-averaged measurements of surface atom configurations by in situ infrared spectroscopy all at identical saturation adsorbate coverage. This is demonstrated for platinum (Pt) nanoparticle surface reconstruction induced by CO adsorption at saturation coverage and elevated (>400 K) temperature, which is relevant for the CO oxidation reaction under cold-start conditions in the catalytic convertor. Through our correlated approach, it is observed that the truncated octahedron shape adopted by bare Pt nanoparticles undergoes a reversible, facet selective reconstruction due to saturation CO coverage, where {100} facets roughen into vicinal stepped high Miller index facets, while {111} facets remain intact.
Catalysts consisting of atomically dispersed Pt (Ptiso) species on CeO2 supports have received recent
interest due to their potential for efficient metal utilization in
catalytic convertors. However, discrepancies exist between the behavior
(reducibility, interaction strength with adsorbates) of high surface
area Ptiso/CeO2 systems and of well-defined
surface science and computational model systems, suggesting differences
in Pt local coordination in the two classes of materials. Here, we
reconcile these differences by demonstrating that high surface area
Ptiso/CeO2 synthesized at low Pt loadings (<0.1%
weight) exhibit resistance to reduction and sintering up to 500 °C
in 0.05 bar H2 and minimal interactions with COproperties
previously seen only for model system studies. Alternatively, Pt loadings
>0.1 weight % produce a distribution of sub-nanometer Pt structures,
which are difficult to distinguish using common characterization techniques,
and exhibit strong interactions with CO and weak resistance to sintering,
even in 0.05 bar H2 at 50 °Cproperties previously
seen for high surface area materials. This work demonstrates that
low metal loadings can be used to selectively populate the most thermodynamically
stable adsorption sites on high surface area supports with atomically
dispersed metals. Further, the site uniformity afforded by this synthetic
approach is critical for the development of relationships between
atomic scale local coordination and functional properties. Comparisons
to recent studies of Ptiso/TiO2 suggest a general
compromise between the stability of atomically dispersed metal catalysts
and their ability to interact with and activate molecular species.
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