Nature of the interaction between rare gas atoms and transition metal doped silicon clusters: the role of shielding effects

Ngân, Vũ Thị; Janssens, Ewald; Claes, Pieterjan; Fielicke, André; Nguyen, Minh Tho; Lievens, Peter

doi:10.1039/c5cp00700c

Cited by 12 publications

(8 citation statements)

References 29 publications

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“…A similar kind of electronic shielding was observed for singly transition metal doped silicon clusters, Si n TM + (n = 5 -10, TM = Cr, Mn, Cu and Zn), interacting with Ar [38], with the difference that for those silicon clusters the shielding was mainly due to s-electrons of the transition metal dopants, while here the shielding is caused by Rh d 𝑧 2 orbitals.…”

Section: Case Study: Al4rh2 + and Al5rh2 +supporting

confidence: 63%

Argon tagging of doubly transition metal doped aluminum clusters: The importance of electronic shielding

Vanbuel

Ferrari

Jia

et al. 2021

The Journal of Chemical Physics

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The interaction of argon with doubly transition metal doped aluminum clusters, Al n TM 2 + (n = 1 -18, TM = V, Nb, Co, Rh), is studied experimentally in the gas phase via mass spectrometry. Density functional theory calculations on selected sizes are used to understand the argon affinity of the clusters, which differ depending on the transition metal dopant. The analysis is focused on two pairs of consecutive sizes: Al 6,7 V 2 + and Al 4,5 Rh 2 + , the largest of each pair showing a low affinity toward Ar. Another remarkable observation is a pronounced drop in reactivity at n = 14, independent on the dopant element. Analysis of the cluster orbitals shows that this feature is not a consequence of cage formation but is electronic in nature. The mass spectra demonstrate a high similarity between the size-dependent reactivity of the clusters with Ar and H 2 . Orbital interactions provide an intuitive link between the two and further establish the importance of precursor states in the reactions of the clusters with hydrogen.

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Section: Case Study: Al4rh2 + and Al5rh2 +supporting

confidence: 63%

Argon tagging of doubly transition metal doped aluminum clusters: The importance of electronic shielding

Vanbuel

Ferrari

Jia

et al. 2021

The Journal of Chemical Physics

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“…Here, however, the decrease is seen after n = 15. A possible explanation could be that at this size, one of the vanadium atoms occupies an endohedral position, and the other is partially shielded, either geometrically [21] or electronically [22]. Understanding the size-dependence of the reactivity of transition metal (doped) clusters in the gas phase is generally not an easy task due to the possibility of low-lying geometric or electronic states (possibly even of a different multiplicity), whose potential energy surfaces (PES) during the reaction with hydrogen might cross that of the ground state.…”

Section: Resultsmentioning

confidence: 99%

Hydrogen Chemisorption on Doubly Vanadium Doped Aluminum Clusters

Vanbuel

Fernández

Jia

et al. 2019

Zeitschrift Für Physikalische Chemie

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The interaction of hydrogen with doubly vanadium doped aluminum clusters, AlnV2+ (n = 1–12), is studied experimentally by time-of-flight mass spectrometry and infrared multiple photon dissociation spectroscopy. The hydrogen binding geometry is inferred from comparison with infrared spectra predicted by density functional theory and shows that for the more reactive clusters the hydrogen adsorbs dissociatively. Three sizes, n = 4, 5 and 7, are remarkably unreactive compared to the other clusters. For larger sizes the reactivity decreases, a behavior that is similar to that of singly vanadium doped aluminum clusters, and that might be attributed to geometric and/or electronic shielding of the dopants. By examining the electronic structure of Al6V2+ and Al7V2+, interactions between the frontier orbitals of the clusters and those of H2 that explain the size-dependent reactivity are identified.

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“…Beyond single atoms, studies have focused on the interaction of small clusters with noble gases [18]. For example, Fielicke and co-workers combined infrared spectroscopy with DFT calculations to investigate the interaction of bimetallic AunAgm + (n+m = 3-5) clusters with Ar [19,20], showing that the bonding strength of the clusters towards Ar decreases with Ag content.…”

Section: Introductionmentioning

confidence: 99%

Benchmarking density functional theory methods for modelling cationic metal–argon complexes

et al. 2021

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Noble gas chemistry is fascinating because noble gases can make formal chemical bonds with metal ions, despite their closed electronic configuration. Argon-metal ion complexes are particularly interesting since their bonding is halfway between dispersion and covalent interactions. Although many metal ion-noble gas complexes have been synthesized, there are still disagreeing theoretical descriptions about their bonding, which is not yet fully understood. Accurate experimental data is important as solid reference for theoretical methodologies, but such data is currently scarce for complexes of metal ion with noble gas atoms. We measured infrared spectra of MArn + (n = 3-5; M = Au, Ag, Pd) complexes and use these spectra as benchmark data for different theory levels within the density functional theory formalism. Several basis sets, exchange-correlation functionals, and the inclusion of dispersion corrections were considered. The agreement between the measured spectra and the calculations strongly depends on the applied level of theory. Functionals of a higher level of complexity do not consistently provide a better agreement with the experiment; this is particularly the case for the B3LYP hybrid functional that performs worse than the PBE GGA functional. On the other hand, the inclusion of dispersion corrections and the use of a large basis sets are crucial for a good description of the interaction between M + and Arn.

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Nature of the interaction between rare gas atoms and transition metal doped silicon clusters: the role of shielding effects

Cited by 12 publications

References 29 publications

Argon tagging of doubly transition metal doped aluminum clusters: The importance of electronic shielding

Argon tagging of doubly transition metal doped aluminum clusters: The importance of electronic shielding

Hydrogen Chemisorption on Doubly Vanadium Doped Aluminum Clusters

Benchmarking density functional theory methods for modelling cationic metal–argon complexes

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