A Surprising Adduct of a closo Cluster

The geometry of the Si ₂ B ₁₀ framework remains nearly unchanged when the Si–Si edge is bridged by an electron-donating amido group. This finding is clearly evident from the single-crystal X-ray structure analysis and ab initio calculations of the uprecedented adduct that is formed by the addition of Et₂N⁻ to o-silaborane (structure depicted bottom right).     

Hexasupersilyloctaindane (tBu3Si)6In8— A Compound with a Novel In8 Cluster Framework

A doubly capped In ₆ octahedron characterizes the structure of the dark green octaindane (tBu₃Si)₆In₈ (see picture), which is obtained from (C₅Me₅)In and tBu₃SiNa in pentane at −78°C. In1/In1′ are the capping atoms, and In2/In2′ form the apexes of the stretched In₆ octahedron. Thus, in agreement with the results of ab initio calculations, the compound can be classified as a hypoprecloso-indane.     

Small Potassium Clusters

The molecules K ₂ , K ₃ , and K ₄ (structure shown on the right) have been isolated in krypton matrices at 15 K and characterized by Raman spectroscopy. Comparison of the experimental data with density functional calculations supports the prediction that potassium clusters are not only bonded by the valence electrons, but that there is also a contribution from the core electrons.     

HCSiF and HCSiCl: The First Detection of Molecules with Formal C≡Si Triple Bonds

Neutralization of [C,H,Si,X] radical cations (X=F, Cl) in conjunction with electronic structure calculations provides the first experimental evidence for the formation of the neutral silynes HC≡SiF and HC≡SiCl, which have nonlinear structures (see picture).     

[B30]−: A Quasiplanar Chiral Boron Cluster

Chirality is vital in chemistry. Its importance in atomic clusters has been recognized since the discovery of the first chiral fullerene, the D₂ symmetric C₇₆. ¹ A number of gold clusters have been found to be chiral, ² raising the possibility to use them as asymmetric catalysts. The discovery of clusters with enantiomeric structures is essential to design new chiral materials with tailored chemical and physical properties. ³ Herein we report the first inherently chiral boron cluster of [B₃₀]^? in a joint photoelectron spectroscopy and theoretical study. The most stable structure of [B₃₀]^? is found to be quasiplanar with a hexagonal hole. Interestingly, a pair of enantiomers arising from different positions of the hexagonal hole are found to be degenerate in our global minimum searches and both should co‐exist experimentally because they have identical electronic structures and give rise to identical simulated photoelectron spectra.     

IR, Raman and theoretical ab initio RHF study of aminoglutethimide — an anticancer drug

A comparative analysis of the IR and Raman spectra of aminoglutethimide (AG) dissolved in CCl₄, CHCl₃ and CH₃CN was performed. Most of the absorption bands were assigned to characteristic group vibrations with the use of the IR and Raman spectra of deuterated AG, glutethimide, N-methyl glutethimide and glutarimide. The AG samples very weakly interacting with the environment were studied with the use of the Ar matrix isolation IR spectra. For comparison, the IR and Raman spectra of the crystalline samples formed by hydrogen-bonded AG molecules were recorded. The spectra were analyzed also in terms of normal modes and the harmonic approximation with the use of the ab initio restricted Hartree-Fock theory. It was found that increasing the solute concentration in CCl₄ and CHCl₃ leads to formation of the autoassociates. In CH₃CN the solute–solvent AG–CH₃CN dimers occur. Possible structures of the associates were theoretically studied on the model systems: the centrosymmetric glutarimide dimer and the linear AG–CH₃CN dimer. By a comparison of the theoretical and experimental spectra we were able to identify several peaks originating from the solute–solvent interactions.     

Reactions of Selected Bismuth Oxide Cluster Cations with Propene

Bismuth oxide cluster ions are reduced by propene in exactly the same way as solid bismuth oxide (Bi₂O₃), which is used as a catalyst. Even in the case of the smallest bismuth oxide cluster ions, such as the Bi₃O₄⁺ isomer shown in the picture, the supposedly unreactive bridging oxygen atom can participate in the alkene oxidation.     

Struktur und Eigenschaften des Methylpentafluorphosphatanions, [CH3PF5]—

Structure and Properties of the Methyltetrafluorophosphate Anion, [CH₃PF₅]^— Methyltetrafluorphosphorane reacts with the fluorides NaF, KF, CsF, and (CH₃)₄NF with formation of the corresponding methylpentafluorophosphates. In case of the K and Cs salts K[CH₃PF₅] · CH₃CN and Cs[CH₃PF₅] · CH₃CN, respectively, are formed using acetonitrile as solvent. The salts are characterized by NMR, IR and Raman spectroscopy. The vibrational frequencies are compared with ab initio calculated data (RHF/6‐31+G*). The RHF/6‐31+G* calculation yields for the almost octahedral anion bond distances of d(PF_eq) = 163.7 pm, d(PF_ax) = 162.0 pm, and d(PC) = 184.8 pm.     

The Silicides M4Si4 with M = Na,K, Rb,Cs, and Ba2Si4 – NMR Spectroscopy and Quantum Mechanical Calculations

The Zintl phases M₄Si₄ with M = Na, K, Rb, Cs, and Ba₂Si₄ feature a common structural unit, the Si₄^4– anion. The coordination of the anions by the cations varies significantly. This allows a systematic investigation of the bonding situation of the anions by ²⁹Si NMR spectroscopy. The compounds were characterized by powder X‐ray diffraction, differential thermal analysis, magnetic susceptibility measurements, ²³Na, ²⁹Si, ⁸⁷Rb, ¹³³Cs NMR spectroscopy, and quantum mechanical calculation of the NMR coupling parameter. The chemical bonding was investigated by quantum mechanical calculations of the electron localizability indicator (ELI). Synthesis of the compounds results for all of them in single phase material. A systematic increase of the isotropic ²⁹Si NMR signal shift with increasing atomic number of the cations is observed by NMR experiments and quantum mechanical calculation of the NMR coupling parameter. The agreement of experimental and theoretical results is very good allowing an unambiguous assignment of the NMR signals to the atomic sites. Quantum mechanical modelling of the NMR shift parameter indicates a dominant influence of the cations on the isotropic ²⁹Si NMR signal shift. In contrast to this a negligible influence of the geometry of the anions on the NMR signal shift is obtained by these model calculations. The origin of the systematic variation of the isotropic NMR signal shift is not yet clear although an influence of the charge transfer estimated by calculation using the QTAIM approach is indicated.     

Unimolecular rearrangement of α-silylcarbenium ions. An ab initio study

The unimolecular rearrangements of hydrogen, methyl and phenyl groups at the Si atom in α-silylcarbenium ions have been investigated using an ab initio molecular orbital method. MP2/6–31 + G^*//HF/6–31G^* calculations predict that all three groups migrate from the Si to an adjacent C_α with no energy barrier. Thus, the silicenium ion is the only stable species in each potential energy surface. The conformation of the benzylsilicenium ion, (C₆H₅)CH₂−SiH₂⁺, indicates that the phenyl ring is significantly bent toward the silyl cationic center in order to interact with the vacant 3p(Si⁺) orbital. In contrast to MP2 results, Hartree-Fuck calculations (both HF/3–21G^* and HF/6–31G^* levels) predict small energy barriers for 1,2-migrations of H and Me (1.4 kcal mol⁻¹ for H migration, and 1.5 kcal mol⁻¹ for Me migration, respectively, at the HF/6–31G^* level). This difference provides convincing evidence that the incorporation of electron correlation is of particular importance in describing the potential energy surface for the rearrangement of α-silylcarbenium ions to silicenium ions. The results of the calculations have also been applied to the possible rearrangement mechanism of α-chlorosilanes to chlorosilanes, assuming that the experimental conditions are favorable toward the generation of ionic species. Various factors which may govern the migratory aptitudes of various R groups, i.e. (1) activation energies, (2) overall reaction energies and (3) the conformational preference of reactants have been investigated. The calculated activation energy obtained, namely the energy for the generation of the silicenium ion and the C⁻¹ ion from an α-chlorosilane, is consistent with the experimental migratory aptitude in the gas phase observed in mass spectrometers.     

A Naphthalene-Like Si1010− Unit in the Novel ∞2[Si2030−] Planar Anion of Sr13Mg2Si20

Two interpenetrating ² _∞ [Si ₂₀ ³⁰⁻ ] polyanions with naphthalene-like Si₁₀¹⁰⁻ building blocks (see picture) characterize the“nonclassical” Zintl phase Sr₁₃Mg₂Si₂₀, which is formed from the elements at 1230–1240 K. The ecliptical stacking of the Si₁₀¹⁰⁻ units leads to one-dimensional conductivity along the stacking direction.     

Unusual conformational properties of 1,3-dimethyl-1,1,3,3-tetrakis(trimethylsilyl)trisilane: A preparative, X-ray, Raman spectroscopic and ab initio study

The heptasilane Me(SiMe₃)₂SiSiH₂SiMe(SiMe₃)₂ was synthesized from Me(SiMe₃)₂SiK and H₂Si(OSO₂CF₃)₂. Crystals suitable for a X-ray single crystal analysis could be grown, with the somewhat surprising result that the two dihedral angles (H₃)CSiSi(H₂)Si are different in the crystal (24.58(10)° and 31.67(11)°). SiSiSi-bonds angles are widened, with values up to 117°. Ab initio calculations at the density functional B3LYP level employing 6-311G(d) basis sets predict minima for five conformers 1-5 with relative energies 0.0, 3.1, 8.2, 10.8 and 18.1 kJ/mol, respectively. Moreover, SiSiSiSi dihedral angles spanning the range 43.5-172.3° are predicted, reflecting the small forces which are required for distorting these angles.In the Raman spectrum of a solution in toluene, three lines at 350, 340 and 330 cm⁻¹ are observed in a wavenumber range which is typical for the SiSi-pulsation of methylated oligosilanes. The relative intensity ratio of the bands is temperature dependent, reflecting the changes in conformer concentrations that occur according to Boltzman’s law. Supported by the ab initio calculations, the Raman band at 350 cm⁻¹ is assigned to an ‘averaged’ conformer 1 and 2, because a rapid interconversion between 1 and 2 has to be assumed due to a small barrier separating them. The bands with wavenumbers 340 and 330 cm⁻¹ originate from conformers 3 and 4. From the Raman spectra, relative energies 0.0 (1 + 2), 2.2 (3) and 6.3 (4) kJ/mol are deduced, the presence of 5 is not observed. Caused by solvent effects, these values differ somewhat from the ab initio results.     

The crystal structure of the interrupted framework silicate K9.6Ca1.2Si12O30 determined from laboratory X-ray diffraction data

The crystal structure of a potassium calcium silicate with composition K_9.6Ca_1.2Si₁₂O₃₀ (or K₈CaSi₁₀O₂₅) has been solved by direct methods aided by distance least squares optimization from laboratory X-ray powder diffraction data. The trigonal compound adopts the non-centrosymmetric space group R3c with the following basic crystallographic data: a=11.13623(5) Å, c=21.9890(2) Å, V=2361.63(2) Å³, Z=3, D_calc=2.617 g cm⁻³. The crystal structure can be classified as an interrupted framework with exclusively Q³-units. It can be thought of as being built from layers parallel to (001) containing isolated six-membered tetrahedral rings in UDUDUD conformation. Corner sharing of tetrahedra belonging to adjacent sheets results in a tetrahedral framework. The framework density of the structure is 15.2 T-atoms/1000 Å³. The coordination sequences are identical for both silicon atoms in the asymmetric unit: 3-6-11-20-32-46-60-80-102-122. The vertex symbols for the two tetrahedral centers are 10₂·10₂·6₁. Topologically, the structure can be described as an Archimedean three-dimensional 3-connected net. It can be derived from the diamond or cristobalite net by removing 20% of the knots. Charge compensation in the structure is achieved by the incorporation of mono- and divalent M-cations (M: K, Ca). These extra-framework ions are coordinated by six to nine oxygen ligands. Ca/K distributions for the five symmetrically independent M-sites were obtained from a combination of bond distance considerations, site occupancy refinements and the bulk chemical composition. The structural characterization is completed by a detailed Raman spectroscopic study. Furthermore, possible implications of the structural chemistry of interrupted framework silicates for the field of silicate glass research are addressed.     

Metathetical Reactions in the System Na(K)PF6 – LiBF4 – Aprotic Media

¹⁹F NMR spectroscopy, X‐ray powder diffraction, elemental analysis, and ab initio quantum chemical calculations were used to study metathetical reactions between potassium or sodium hexafluorophosphate and lithium tetrafluoroborate in a mixture of propylene carbonate (PC) – dimethyl carbonate (DMC). It was shown that the increase in size of the cations in the second coordination sphere from Na⁺ to K⁺ results in an increase of the equilibrium conversion. This is in agreement with the influence of the cation size on the solubility of tetrafluoroborates in the media investigated.