Structural studies of ligand stabilized Ni/Ga clusters by means of vibrational spectroscopy and theoretical calculations

Structural studies of ligand stabilized Ni/Ga clusters by means of vibrational spectroscopy and theoretical calculations

In order to explain the different catalytic activity in hydrogenation of two new intermetallic Ni/Ga clusters, [Ga7](NiCp*)6 (1A) and [NiGa6](NiCp*)6 (1B) (Cp* = C5Me5), investigations of structure–function relationship have been performed based on Raman and infrared (IR) spectroscopy and theoretica...

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Bibliographic Details
Published in:Journal of Raman spectroscopy Vol. 52; no. 12; pp. 2317 - 2337
Main Authors: Mink, János, Staiger, Lena, Muhr, Maximilian, Gemel, Christian, Drees, Markus, Hajba, László, Mihály, Judith, Németh, Csaba, Lokshin, Boris V., Hemmer, Karina, Schütz, Max, Cokoja, Mirza, Fischer, Roland A.
Format: Journal Article
Language:English
Published: Bognor Regis Wiley Subscription Services, Inc 01-12-2021
Subjects:
Bonding strength
Catalytic activity
cluster catalysis
Clusters
Constants
Coordination compounds
Density functional theory
Deuteration
Deuterium
DFT
far infrared
Hydrogenation
infrared
Infrared spectroscopy
Ligands
Mathematical analysis
Raman
Spectroscopy
Spectrum analysis
Stretching
Structure-function relationships
Vibrations
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Summary:In order to explain the different catalytic activity in hydrogenation of two new intermetallic Ni/Ga clusters, [Ga7](NiCp*)6 (1A) and [NiGa6](NiCp*)6 (1B) (Cp* = C5Me5), investigations of structure–function relationship have been performed based on Raman and infrared (IR) spectroscopy and theoretical (density functional theory [DFT] and normal coordinate) calculations. Full interpretation of the Raman, far‐IR, and mid‐IR spectra of these dark colored solids has been proposed. Based on the overview of metal–Cp* complexes, all the 14 characteristic Cp*− skeletal fundamental modes have been identified. By comparison of the NiCp* stretching and tilting external modes (350–380 cm−1), their force constants, and bond lengths, cluster 1B exhibited slightly stronger metal–ligand bonding. Vibrations of Ga7 and NiGa6 cluster cores showed that the stretching wavenumbers and force constants of NiGa (100–350 cm−1) and GaGa (60–250 cm−1) bonds are higher for cluster 1B, in agreement with the shorter averaged experimental and calculated bond lengths of GaGa bonds (2.873 and 2823 Å for clusters 1A and 1B, respectively). Cluster hydrogenation experiments with H2 and D2 showed strong NiH and ND stretching features (at 1750 and 1260 cm−1, respectively), and at the same time, characteristic bands of self‐hydrogenated Cp*H and remained nondegraded clusters have been detected. The extent of HD exchange in cluster deuteration was obtained about 1.5 times more effective with cluster 1B than cluster 1A. The stronger hydrogen or deuterium uptake by cluster 1B and the more intensive self‐hydrogenation of Cp* clearly support the higher hydrogenation activity of cluster 1B compared with that of 1A. The different hydrogenation activity of two new intermetallic Ni/Ga clusters, [Ga7](NiCp*)6 (1A) and [NiGa6](NiCp*)6 (1B) (Cp* = C5Me5), has been explained by Raman and IR spectroscopy and theoretical (DFT and normal coordinate) calculations. The distribution of calculated skeletal stretching modes is shown of cluster 1A under the experimental Raman spectrum. The stronger hydrogen or deuterium uptake in aqueous solutions by cluster 1B and the more intensive self‐hydrogenation of Cp* support the higher hydrogenation activity of cluster 1B compared with that of 1A.
ISSN:0377-0486
1097-4555
DOI:10.1002/jrs.6199