The interaction of ethylene with free gold cluster cations: infrared photodissociation spectroscopy combined with electronic and vibrational structure calculations

Lang, Sandra M.; Bernhardt, Thorsten M.; Bakker, Joost M.; Yoon, Bokwon; Landman, Uzi

doi:10.1088/1361-648x/aaeafd

Cited by 14 publications

(25 citation statements)

References 61 publications

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“…The donation/back‐donation mechanism of ethylene adsorption on gold clusters was inferred from changes in the total charge of the adsorbate and the clusters bond lengths . It was shown that CO adsorption on Pd clusters elongates the Pd−Pd and C−O bonds, which supports a donation/back‐donation mechanism .…”

Section: Introductionmentioning

confidence: 92%

“…The bond formation and bond breaking processes are confined to the catalytically active sites, which can be modelled by small clusters. [27] Beside the calculation of the reactione nergy,t he analysisa nd the understanding of the chemicali nteractions between catalyst andr eagents is important for rational catalyst design.F or cluster-adduct complexes, the changes in bond lengths and charges, [28][29][30] the frontier orbital and population analysis, [31][32][33] ionization potentials and electron affinities, [34] and NBO analysis, [35] are commonlyu sed to analyse the chemical bonding.…”

Section: Introductionmentioning

confidence: 99%

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Non‐covalent Interactions and Charge Transfer between Propene and Neutral Yttrium‐Doped and Pure Gold Clusters

Barabás

Vanbuel

Ferrari

et al. 2019

Chemistry A European J

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The dopant and size‐dependent propene adsorption on neutral gold (Aun) and yttrium‐doped gold (Aun−1Y) clusters in the n=5–15 size range are investigated, combining mass spectrometry and gas phase reactions in a low‐pressure collision cell and density functional theory calculations. The adsorption energies, extracted from the experimental data using an RRKM analysis, show a similar size dependence as the quantum chemical results and are in the range of ≈0.6–1.2 eV. Yttrium doping significantly alters the propene adsorption energies for n=5, 12 and 13. Chemical bonding and energy decomposition analysis showed that there is no covalent bond between the cluster and propene, and that charge transfer and other non‐covalent interactions are dominant. The natural charges, Wiberg bond indices, and the importance of charge transfer all support an electron donation/back‐donation mechanism for the adsorption. Yttrium plays a significant role not only in the propene binding energy, but also in the chemical bonding in the cluster‐propene adduct. Propene preferentially binds to yttrium in small clusters (n<10), and to a gold atom at larger sizes. Besides charge transfer, relaxation also plays an important role, illustrating the non‐local effect of the yttrium dopant. It is shown that the frontier molecular orbitals of the clusters determine the chemical bonding, in line with the molecular‐like electronic structure of metal clusters.

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Section: Introductionmentioning

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Non‐covalent Interactions and Charge Transfer between Propene and Neutral Yttrium‐Doped and Pure Gold Clusters

Barabás

Vanbuel

Ferrari

et al. 2019

Chemistry A European J

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“…In contrast, νC−C is known to be very sensitive to the C−C bond lengths. 12 For example, for small hydrocarbons νC−C blue-shifts almost linearly from 995 cm −1 for C 2 H 6 with d(C−C) = 1.535 Å to 1623 cm −1 for C 2 H 4 with d(C = C) = 1.339 Å and 1974 cm −1 for C 2 H 2 with d(C C) = 1.203 Å. 31,32 This suggests that the blue-shift of ν s OCO + νC−C is mainly caused by a shortening of the C−C bond; the observed shift of about 30−45 cm −1 might already be caused by a change of the C−C bond length of <0.05 Å.…”

Section: Influence Of Cluster Composition On the C−cmentioning

confidence: 99%

Cluster Size Dependent Interaction of Free Manganese Oxide Clusters with Acetic Acid and Methyl Acetate

et al. 2021

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We have employed infrared multiple-photon dissociation (IR-MPD) spectroscopy together with density functional theory (DFT) calculations to study the interaction of series of subnanometer sized manganese oxide clusters, Mn x O y + (x = 1–6, y = 0–9) with acetic acid (HOAc) and methyl acetate (MeOAc). Reaction with HOAc leads to strongly cluster size and composition dependent IR-MPD spectra, indicating molecular adsorption on MnO x + clusters and thermodynamically favorable but kinetically hampered HOAc dissociation (deprotonation) on Mn2O4 + and Mn3O5 +. Other cluster sizes exhibit the preferred formation of a dissociative bidentate chelating structure. In contrast to HOAc, all clusters bind MeOAc via the carbonyl group as an intact molecule, and dissociation appears to be kinetically hindered under the given experimental conditions.

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“…65 The NO stretching frequency of AunNO + complexes exhibits marked odd-even alternation, as the unpaired electron in the l Aun + (n = even) clusters efficiently donates into the NO * orbital, efficiently activating it. 7 Infrared studies of other adsorbates (e.g., CO, 7,66 methane, 67 methanol, [68][69][70] ethanol, 71 and ethene 72 ) on gold clusters suggest alternative binding mechanisms for which odd-even size effects are less clear. All small gold clusters selectively dissociate a single C-H bond in CH4 but, whilst CH4 binding energies to Aun + show a clear size dependence, 73 this is not reflected in the IR-MPD spectra.…”

Section: Introductionmentioning

confidence: 99%

Infrared Study of OCS Binding and Size-Selective Reactivity with Gold Clusters, Au_n⁺ (n = 1–10)

et al. 2020

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OCS binding to and reactivity with isolated gold cluster cations, Aun + (n = 1-10) has been studied by infrared multiple photon dissociation (IR-MPD) spectroscopy in conjunction with quantum chemical calculations. The distribution of complexes AunSx(OCS)m + formed reflects the relative reactivity of different cluster sizes with OCS, under the multiple collision conditions of our ablation source. The IR-MPD spectra of Aun(OCS) + (n = 3-10) clusters are interpreted in terms of either µ 1 or µ 2 S-binding motifs. Analysis of the fragmentation products following infrared excitation of parent Aun(OCS) + clusters reveals strongly size-selective (odd-even) branching ratios for OCS and CO loss, respectively. CO loss signifies infrared-driven OCS decomposition on the cluster surface and is observed to occur predominantly on even n clusters (i.e., those with odd electron counts). The experimental data, including fragmentation branching ratios, are consistent with calculated potential energy landscapes, in which the initial species trapped are molecularlybound entrance channel complexes, rather than global minimum inserted structures. Attempts to generate Rhn(OCS) + and Ptn(OCS) + equivalents failed; only sulfide reaction products were observed in the mass spectrum, even after cooling the cluster source to -100℃. gold clusters have revealed optimum activity when 60% of gold is positively charged, [28][29][30] and trace water levels can perturb the electron density on a gold catalyst particle enhancing its reactivity. 12 Gas-phase cluster studies can achieve exquisite control of both cluster size and charge state. Mass spectrometry techniques permit the study of trends in reactivity and charge characteristics, which may guide target properties for deposited particles. [31][32][33] Such fundamental studies, using a range of techniques, [34][35][36] including ion mobility, [37][38][39] and visible photodissociation spectroscopy, 40 continue to reveal unique physico-chemical features in gold clusters, Aun +/0/-, such as the transformation from planar to three-dimensional ground state structures at surprisingly large cluster sizes (n = 8,11,12 for cations, neutrals, and anions, respectively)another result arising from relativistic effects. These and other investigations of Aun +/0/clusters often reveal oscillating trends with increasing cluster size, n, in properties including cluster stability, dissociation energy, ionisation potential, electron affinity, fragmentation pathways and HOMO-LUMO gap. 20,[41][42][43][44][45][46][47][48] Due to the electronic structure of gold, the cluster size, n, and charge effects are very closely linked, 49 and many observations have been interpreted in terms of electron counting models in which each gold atom, with the [Xe]4f 14 5d 10 6s 1 configuration, is considered as monovalent, similar to alkali metals. 20,50 Within such jellium models, 51 gold clusters exhibit electronic shell structures with magic numbers corresponding to shell closures at 8, 18, 20, etc.. [52][53] Similarly, oscillating ...

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The interaction of ethylene with free gold cluster cations: infrared photodissociation spectroscopy combined with electronic and vibrational structure calculations

Cited by 14 publications

References 61 publications

Non‐covalent Interactions and Charge Transfer between Propene and Neutral Yttrium‐Doped and Pure Gold Clusters

Non‐covalent Interactions and Charge Transfer between Propene and Neutral Yttrium‐Doped and Pure Gold Clusters

Cluster Size Dependent Interaction of Free Manganese Oxide Clusters with Acetic Acid and Methyl Acetate

Infrared Study of OCS Binding and Size-Selective Reactivity with Gold Clusters, Au_n⁺ (n = 1–10)

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The interaction of ethylene with free gold cluster cations: infrared photodissociation spectroscopy combined with electronic and vibrational structure calculations

Cited by 14 publications

References 61 publications

Non‐covalent Interactions and Charge Transfer between Propene and Neutral Yttrium‐Doped and Pure Gold Clusters

Non‐covalent Interactions and Charge Transfer between Propene and Neutral Yttrium‐Doped and Pure Gold Clusters

Cluster Size Dependent Interaction of Free Manganese Oxide Clusters with Acetic Acid and Methyl Acetate

Infrared Study of OCS Binding and Size-Selective Reactivity with Gold Clusters, Aun+ (n = 1–10)

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Infrared Study of OCS Binding and Size-Selective Reactivity with Gold Clusters, Au_n⁺ (n = 1–10)