Small tin cluster anions: Transition from quasispherical to prolate structures

Oger, Esther; Kelting, Rebecca; Weis, Patrick; Lechtken, Anne; Schooss, Detlef; Crawford, Nathan R. M.; Ahlrichs, Reinhart; Kappes, Manfred M.

doi:10.1063/1.3094320

Cited by 55 publications

(60 citation statements)

References 65 publications

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“…Sn 7 is an apparent exception. Whereas Sn 7 is observed as a dominant fragment in collision induced dissociation studies of smaller clusters, 11 it was not found as a discrete structural element ͑pentagonal bipyramid͒ within the medium sized clusters considered here. However, the Sn 7 unit is found as higher energy isomer.…”

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confidence: 92%

“…Interestingly, the 15-atom subunit strongly resembles the ground state structure of Sn 15 − . 11 Several low-energy isomers were found, of which only the tentative ground state ͑25-1͒ is shown in Fig. 1.…”

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confidence: 99%

“…In addition, several other, purely theoretical investigations have focused on the geometric structures of small tin cluster anions. 10 Recently, we have studied the structural evolution of small tin cluster anions up to n = 15 by a combined experimental and theoretical approach, 11 − we demonstrate that anionic clusters in the intermediate size range in fact have prolate shapes. Furthermore, the assigned structures all conform to a common "segmented cluster chain" motif comprising dimers of particularly stable subunits.…”

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confidence: 99%

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Communications: Tin cluster anions (Snn−, n=18, 20, 23, and 25) comprise dimers of stable subunits

Lechtken

Drebov

Ahlrichs

et al. 2010

The Journal of Chemical Physics

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confidence: 92%

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confidence: 99%

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confidence: 99%

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Communications: Tin cluster anions (Snn−, n=18, 20, 23, and 25) comprise dimers of stable subunits

Lechtken

Drebov

Ahlrichs

et al. 2010

The Journal of Chemical Physics

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“…On the basis of ion mobility measurements, it has been concluded that the morphology follows the pattern found for Si and Ge but not that of Pb (Shvartsburg & Jarrold 1999). Tin cluster anions have not been investigated as much as the cations; recent reviews of the literature can be found in Oger et al (2009) and Lechtken et al (in preparation). We just mention the recent work of Cui et al (2006) in which the existence of a relatively stable Sn 2− 12 dianion with a perfect icosahedral structure was inferred from the photoelectron spectrum of KSn − 12 .…”

Section: Tin Cluster Anions: From Spherical To Prolate To Clusters Ofmentioning

confidence: 99%

Quantum chemical treatments of metal clusters

Weigend

Ahlrichs

2010

Phil. Trans. R. Soc. A.

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This work focuses on finding and rationalizing the building principles of clusters with approximately 300 atoms of different types of metals: main group elements (Al, Sn), alkaline earth metals (Mg), transition metals (Pd) and clusters consisting of two different elements (Ir and Pt). Two tools are inevitable for this purpose: (i) quantum chemical methods that are able to treat a given cluster with both sufficient accuracy and efficiency and (ii) algorithms that are able to systematically scan the (3n−6)-dimensional potential surface of an n-atomic cluster for promising isomers. Currently, the only quantum chemical method that can be applied to metal clusters is density functional theory (DFT). Other methods either do not account for the multi-reference character of metal clusters or are too expensive and thus can be applied only to clusters of very few atoms, which usually is not sufficient for studying the building principles. The accuracy of DFT is not known a priori, but extrapolations to bulk values from calculated series of data show satisfying agreement with experimental data. For scans of the potential surface, simulated annealing techniques or genetic algorithms were used for the smaller clusters (approx. 20-30 atoms), and for the larger clusters considerations were restricted to selected packings and shapes. For the mixed-metallic clusters, perturbation theory turned out to be efficient and successful for finding the most promising distributions of the two atom types at the different sites.

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“…Note that in all comparative IMS and TIED studies performed so far on metal clusters we have observed no indication for metastable species. [36][37][38] One possible explanation for these findings is that isomer II is lost before the structure dependent measurement is taken, i.e., during injection into the drift cell in IMS or during trapping in the TIED experiment. In both cases a fraction of the lab frame kinetic energy (∼300 eV IMS, ∼25 eV TIED) is converted (via collisions with helium) into internal excitation of the cluster.…”

Section: A Structuresmentioning

confidence: 96%

Structures of small bismuth cluster cations

Kelting

Baldes²,

Schwarz³

et al. 2012

The Journal of Chemical Physics

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The structures of bismuth cluster cations in the range between 4 and 14 atoms have been assigned by a combination of gas phase ion mobility and trapped ion electron diffraction measurements together with density functional theory calculations. We find that above 8 atoms the clusters adopt prolate structures with coordination numbers between 3 and 4 and highly directional bonds. These open structures are more like those seen for clusters of semiconducting-in-bulk elements (such as silicon) rather than resembling the compact structures typical for clusters of metallic-in-bulk elements. An accurate description of bismuth clusters at the level of density functional theory, in particular of fragmentation pathways and dissociation energetics, requires taking spin-orbit coupling into account. For n = 11 we infer that low energy isomers can have fragmentation thresholds comparable to their structural interconversion barriers. This gives rise to experimental isomer distributions which are dependent on formation and annealing histories.

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Small tin cluster anions: Transition from quasispherical to prolate structures

Cited by 55 publications

References 65 publications

Communications: Tin cluster anions (Snn−, n=18, 20, 23, and 25) comprise dimers of stable subunits

Communications: Tin cluster anions (Snn−, n=18, 20, 23, and 25) comprise dimers of stable subunits

Quantum chemical treatments of metal clusters

Structures of small bismuth cluster cations

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