Theoretical Study of Hydrogen Adsorption on Au@Pd Icosahedral Nanoparticle

Sandoval, Mario G.; Luna, Roman Jorge; Brizuela, G.; Pereira, Aline O.; Miranda, Caetano R.; Jasen, Paula Verónica

doi:10.1021/acs.jpcc.7b00286

Cited by 14 publications

(9 citation statements)

References 71 publications

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“…On the other hand, chemically-and physically-synthesized AuPd NPs are attracting a great deal of interest due to the synergic effect of the two combined metals, Au being an excellent plasmonic material, and Pd an excellent catalytic material [22][23][24]29]. In addition to catalytic applications, these systems can exploit their functional properties in sensor applications [30][31][32], plasmonics [30,33], photocatalysis [34], hydrogen storage [35], etc. In general, the properties of NPs bridge those of bulk and atomic systems (size effects), and such properties are wide-range modifiable by the manipulation of the structural ones.…”

Section: Introductionmentioning

confidence: 99%

Experimental Analysis on the Molten-Phase Dewetting Characteristics of AuPd Alloy Films on Topographically-Structured Substrates

Ruffino¹

2017

Metals

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AuPd nanoparticles are formed on fluorine-doped tin oxide (FTO) by a nanosecond laser irradiation-induced dewetting process of deposited AuPd films. In particular, we analyze the effect of the surface topography of the substrate on the dewetting process and, so, on the final mean size of the formed nanoparticles. In fact, we used two supporting FTO substrates differing in the surface topography: we used a FTO layer which is un-intentionally patterned since it is formed by FTO pyramids randomly distributed on the glass slide as result of the deposition process of the same FTO layer, namely substrate A. We used, also, a further FTO substrate, namely substrate B, presenting, as a result of a chemical etching process, a higher roughness and higher mean distance between nearest-neighbor pyramids with respect to substrate A. The results concerning the size of the obtained AuPd NPs by the laser irradiations with the laser fluence fixed shows that the substrate topography impacts on the dewetting process. In particular, we found that below a critical thickness of the deposited AuPd film, the NPs formed on substrates A and B have similar size and a similar trend for the evolution of their size versus the film thickness (i.e., the dewetting process is not influenced by the substrate topography since the film does not interact with the substrate topography). On the other hand, however, above a critical thickness of the deposited AuPd film, the AuPd NPs show a higher mean size (versus the film thickness) on substrate B than on substrate A, indicating that the AuPd film interacts with the substrate topography during the dewetting process. These results are quantified and discussed by the description of the substrate topography effect on the excess of chemical potential driving the dewetting process.

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Section: Introductionmentioning

confidence: 99%

Experimental Analysis on the Molten-Phase Dewetting Characteristics of AuPd Alloy Films on Topographically-Structured Substrates

Ruffino¹

2017

Metals

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“…After the immobilization of the metals, no new reduction peaks were detected, confirming that the reduction of Au and Pd species was efficient upon the NaBH 4 usage; however, the shifting of the reduction temperatures to lower values (814 and 1009 °C) after the metal impregnation can be attributed to some sort of interaction between the metals and the support. The observation can be explained by H 2 absorption on the Pd or Au−Pd surfaces, which weaken the H−H bond, decreasing the H 2 activation barrier. Thus, it is more readily available for the strontium compound reduction.…”

Section: Resultsmentioning

confidence: 99%

Au−Pd Selectivity‐switchable Alcohol‐oxidation Catalyst: Controlling the Duality of the Mechanism using a Multivariate Approach

et al. 2019

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Supported gold‐palladium nanoparticles are highly selective catalysts for the oxidation of alcohols. However, little is known about how integrated reaction conditions can affect the chemoselectivity of a specific catalytic system. Herein, a novel Au−Pd selectivity‐switchable catalyst supported on SrCO3 is reported; and a multivariate optimization was suggested as the key process to better understand the formation of the products. The optimization approach considered temperature, pressure, time of reaction, and Au : Pd molar ratio, and settled that the temperature and Au : Pd molar ratio showed an important effect on the ester yield, while just the metal molar ratio significantly influenced the selectivity for the aldehyde. Thus, taking into consideration the experimental data and optimized conditions, we were able to efficiently switch the selectivity by just changing the pressure of the system in a benzyl alcohol oxidation reaction. In addition, we proposed that the presence of O2 implies that there are two catalytic pathways, which leads to different selectivity, allowing us to bring some mechanistic insights dealing with the duality of the mechanism. Such outcomes are based on dense experimental results and characterizations (FT‐IR, Rietveld refinement, XPS, H2‐TPR, and EDS‐STEM). The catalyst was also very stable, presenting activity up to 6 runs without loss of activity and selectivity, under certain reaction conditions.

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“…The promising role of clusters in further advances for hydrogen storage materials is discussed by Jasen and coworkers, throughout the theoretical study of icosahedral Au@Pd bimetallic nanoparticles with diameter below 2 nm, involving a related 55‐atom regular icosahedra, with 42 atoms lying on the surface of an inner 13‐atom core (similar to M 13 in Figure ) . It was shown that the studied nanoclusters dissociate from the H[sbond]H bond more easily in comparison to Pd/Au surface, where the metal–metal bond remains almost unaffected indicating that the overall cluster is involved in the adsorption of H. Charge transfer shows that Au@Pd nanoparticle has a capacitive behavior, indicating that nanoparticles could adsorb more dissociated H atoms than the periodic surface, with a lesser modification of its metal–metal interaction supporting the overall cluster.…”

Section: Bare Superatomsmentioning

confidence: 94%

Bonding and properties of superatoms. Analogs to atoms and molecules and related concepts from superatomic clusters

Tlahuice‐Flores

Muñoz-Castro

2018

Int J of Quantum Chemistry

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Expanding the versatility of well‐defined clusters is a fundamental issue in the design of functional nanostructures. In this sense, the concept of super atoms allows us to gain a deeper understanding and rationalization of the different properties of metallic clusters by invoking more familiar aspects. Recently, the super atoms appear to be intimately connected to other relevant tools of great chemical significance which enhance a rational design of superatomic clusters mimicking more complex structures and networks. Here, we expect to account for the research efforts from Latin American groups in the field, highlighting their valuable contribution to superatomic and related clusters.

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Theoretical Study of Hydrogen Adsorption on Au@Pd Icosahedral Nanoparticle

Cited by 14 publications

References 71 publications

Experimental Analysis on the Molten-Phase Dewetting Characteristics of AuPd Alloy Films on Topographically-Structured Substrates

Experimental Analysis on the Molten-Phase Dewetting Characteristics of AuPd Alloy Films on Topographically-Structured Substrates

Au−Pd Selectivity‐switchable Alcohol‐oxidation Catalyst: Controlling the Duality of the Mechanism using a Multivariate Approach

Bonding and properties of superatoms. Analogs to atoms and molecules and related concepts from superatomic clusters

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