We explored the size-dependent activity and selectivity of Zn nanoparticles (NPs) for the electrochemical CO reduction reaction (CORR). Zn NPs ranging from 3 to 5 nm showed high activity and selectivity (∼70%) for CO production, whereas those above 5 nm exhibited bulk-like catalytic properties. In addition, a drastic increase in hydrogen production was observed for the Zn NPs below 3 nm, which is associated with the enhanced content of low-coordinated sites on small NPs. The presence of residual cationic Zn species in the catalysts was also revealed during CORR via operando X-ray absorption fine-structure spectroscopy measurements. Such species are expected to play a role in the selectivity trends obtained. Our findings can serve as guidance for the development of highly active and CO-selective Zn-based catalysts for CORR.
Surface segregation, restructuring, and sintering phenomena in size-selected copper-nickel nanoparticles (NPs) supported on silicon dioxide substrates were systematically investigated as a function of temperature, chemical state, and reactive gas environment. Using near-ambient pressure (NAP-XPS) and ultrahigh vacuum X-ray photoelectron spectroscopy (XPS), we showed that nickel tends to segregate to the surface of the NPs at elevated temperatures in oxygen- or hydrogen-containing atmospheres. It was found that the NP pretreatment, gaseous environment, and oxide formation free energy are the main driving forces of the restructuring and segregation trends observed, overshadowing the role of the surface free energy. The depth profile of the elemental composition of the particles was determined under operando CO hydrogenation conditions by varying the energy of the X-ray beam. The temperature dependence of the chemical state of the two metals was systematically studied, revealing the high stability of nickel oxides on the NPs and the important role of high valence oxidation states in the segregation behavior. Atomic force microscopy (AFM) studies revealed a remarkable stability of the NPs against sintering at temperatures as high as 700 °C. The results provide new insights into the complex interplay of the various factors which affect alloy formation and segregation phenomena in bimetallic NP systems, often in ways different from those previously known for their bulk counterparts. This leads to new routes for tuning the surface composition of nanocatalysts, for example, through plasma and annealing pretreatments.
Surface segregation
and restructuring in size-selected CuNi nanoparticles
were investigated via near-ambient pressure X-ray photoelectron spectroscopy
(NAP-XPS) at various temperatures in different gas environments. Particularly
in focus were structural and morphological changes occurring under
CO
2
hydrogenation conditions in the presence of carbon
monoxide (CO) in the reactant gas mixture. Nickel surface segregation
was observed when only CO was present as adsorbate. The segregation
trend is inverted in a reaction gas mixture consisting of CO
2
, H
2
, and CO, resulting in an increase of copper concentration
on the surface. Density functional theory calculations attributed
the inversion of the segregation trend to the formation of a stable
intermediate on the nanocatalyst surface (CH
3
O) in the
CO-containing reactant mixture, which modifies the nickel segregation
energy, thus driving copper to the surface. The promoting role of
CO for the synthesis of methanol was demonstrated by catalytic characterization
measurements of silica-supported CuNi NPs in a fixed-bed reactor,
revealing high methanol selectivity (over 85%) at moderate pressures
(20 bar). The results underline the important role of intermediate
reaction species in determining the surface composition of bimetallic
nanocatalysts and help understand the effect of CO cofeed on the properties
of CO
2
hydrogenation catalysts.
The influence of the crystallographic orientation on surface segregation and alloy formation in model PdCu methanol synthesis catalysts was investigated in situ using near-ambient pressure X-ray photoelectron spectroscopy under CO 2 hydrogenation conditions. Combined with scanning tunneling microscopy and density functional theory calculations, the study showed that submonolayers of Pd undergo spontaneous alloy formation on Cu(110) and Cu(100) surfaces in vacuum, whereas they do not form an alloy on Cu(111). Upon heating in H 2 , inward diffusion of Pd into the Cu lattice is favored, facilitating alloying on all Cu surfaces. Under CO 2 hydrogenation reaction conditions, the alloying trend becomes stronger, promoted by the reaction intermediate HCOO*, especially on Pd/Cu(110). This work demonstrates that surface alloying may be a key factor in the enhancement of the catalytic activity of PdCu catalysts as compared to their monometallic counterparts. Furthermore, it sheds light on the hydrogen activation mechanism during catalytic hydrogenation on copper-based catalysts.
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