Bonding interactions of metal clusters [Mn (M= Cu, Ag, Au; n=1-4)] with ammonia. Are the metal clusters adequate as a model of surfaces?

Martínez, Ana

doi:10.1590/s0103-50532005000300007

Cited by 14 publications

(9 citation statements)

References 28 publications

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“…Several early investigations have demonstrated the reactivity of metal clusters with ammonia, − an example of which is shown in Figure , where the interesting clusters Al 11 NH 3 – and Al 12 NH 3 – dominated the products. Theoretical calculations revealed that the presence of ammonia leads to geometric distortion of Al 12 – together with dissociation of the NH 3 molecule, the N and H atoms of which transfer onto the Al cluster, resulting in a reorganized minimum-energy structure.…”

Section: Reactivity Of Metal Clusters With Polar Moleculesmentioning

confidence: 99%

Reactivity of Metal Clusters

2016

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We summarize here the research advances on the reactivity of metal clusters. After a simple introduction of apparatuses used for gas-phase cluster reactions, we focus on the reactivity of metal clusters with various polar and nonpolar molecules in the gas phase and illustrate how elementary reactions of metal clusters proceed one-step at a time under a combination of geometric and electronic reorganization. The topics discussed in this study include chemical adsorption, addition reaction, cleavage of chemical bonds, etching effect, spin effect, the harpoon mechanism, and the complementary active sites (CAS) mechanism, among others. Insights into the reactivity of metal clusters not only facilitate a better understanding of the fundamentals in condensed-phase chemistry but also provide a way to dissect the stability and reactivity of monolayer-protected clusters synthesized via wet chemistry.

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Section: Reactivity Of Metal Clusters With Polar Moleculesmentioning

confidence: 99%

Reactivity of Metal Clusters

2016

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“…This distance is consistent with previously calculated bond lengths of amines on Ag surfaces. 59,60 The presence of a covalent Ag−N bond in this configuration is further supported by the charge transfer between Ag(100) and the amine, as indicated by the charge density difference relative to the potential of zero free charge (PZFC) (Figure 5a). A covalent bond is also supported by the observed population of Ag−N bonding orbitals below the Fermi level, as determined from crystal orbital Hamilton population analysis (SI, Figure S5).…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Mechanistic Insights about Electrochemical Proton-Coupled Electron Transfer Derived from a Vibrational Probe

et al. 2021

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Proton-coupled electron transfer (PCET) is a fundamental step in a wide range of electrochemical processes, including those of interest in energy conversion and storage. Despite its importance, several mechanistic details of such reactions remain unclear. Here, we have combined a proton donor (tertiary ammonium) with a vibrational Stark-shift probe (benzonitrile), to track the process from the entry of the reactants into the electrical double layer (EDL), to the PCET reaction associated with proton donation to the electrode, and the formation of products. We have used operando vibrational spectroscopy and periodic density functional theory under electrochemical bias to assign the reactant and product peaks and their Stark shifts. We have identified three main stages for the progress of the PCET reaction as a function of applied potential. First, we have determined the potential necessary for desolvation of the reactants and their entry into the polarizing environment of the EDL. Second, we have observed the appearance of product peaks prior to the onset of steady state electrochemical current, indicating formation of a stationary population of products that does not turn over. Finally, more negative of the onset potential, the electrode attracts additional reactants, displacing the stationary products and enabling steady state current. This work shows that the integration of a vibrational Stark-shift probe with a proton donor provides critical insight into the interplay between interfacial electrostatics and heterogeneous chemical reactions. Such insights cannot be obtained from electrochemical measurements alone.

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“…29 These are likely to originate from chelation of the metal surface by the lone electron pair on the nitrogen and the accompanying interfacial polarization effects. [44][45][46] Indeed, SKPM measurements on freshly evaporated gold coated by our interlayers presented dipole shis of À0.6 up to À0.7 eV, regardless of the chemical and physical (linear or three dimensional) structures of the interlayers. Similar to the gold interface, comparable interfacial dipoles are expected for the interfaces between the interlayer materials and the evaporated aluminium electrode.…”

Section: Resultsmentioning

confidence: 99%