The maximum hardness and minimum polarizability principles in accordance with the Bent rule

Energies, hardness values and polarizabilities for different isomers of SF₄, SF₄O molecules and a family of PCl_xF_5−x, (x=1,2,3,4) compounds are calculated at the density functional level of theory (B3LYP) using different basis sets (6-31G**, 6-311G**, 6-31++G and 6-311++G). For all molecules and in all cases the Bent rule is confirmed with the stability orders, which is obtained from the calculated energies. It is also found that for each molecule the isomer in which the more electronegative atom occupies the axial position has maximum hardness; and therefore according to the Maximum Hardness Principle (MHP), it must be the most stable isomer. This result is consistent with the Bent rule, but for some cases in which there are more than two isomers, the obtained trends for the stability are not in accordance with this rule. On the other hand, since the calculation of dipole polarizability is very sensitive to the quality of the selected basis set, only for those calculations in which diffuse basis sets are used the obtained trends of stability from the Minimum Polarizability Principle (MPP) are the same as those which are predicted from the Bent rule. It seems that when there are more than two isomers for a molecule both the MHP and MPP can only predict the most stable isomer and cannot predict the correct trend for the stability of the isomers.     

DFT studies and AIM analysis of AlN-polycycles

The structure and properties of AlN-polycycles were studied by DFT (density functional theory) method. The results of calculations were obtained at B3LYP/6-311G(d, p) level on model species. Topological parameters such as electron density, its Laplacian, kinetic electron energy density, potential electron energy density, and total electron energy density at the ring critical points (RCP) from Bader’s ‘Atoms in molecules’ (AIM) theory were analyzed in detail. These results indicate a good correlation between ρ(3, +1), G(r), H(r), and V(r) averaged values and hardness of AlN-polycycles. The aromaticity of all molecules has been studied by nucleus-independent chemical shift. There is a linear correlation between ΣNICS(0.0)_molecule values and polarizability.     

Molecular impurities in helium clusters

We review recently developed theories of molecular interactions with helium clusters. Ground state energies and structures are obtained from Monte Carlo and density functional calculations for a variety of impurities and a range of cluster sizes. Of particular interest are chemical potentials, location of the impurity, and shape of the helium density surrounding it. Included in the work summarized here are results for light molecules (H₂ and D₂) which interact weakly with He and results for heavier molecules (Cl₂ and SF₆) which interact more strongly with He. Finally, theoretical and experimental results are compared for SF₆ in helium clusters.     

S 2p photoabsorption of the SF5CF3 molecule: Experiment,theory and comparison with SF6

The S 2p core excitation spectrum of the SF₅CF₃ molecule has been measured in the total ion yield mode. It resembles a lot the analogous spectrum of SF₆, also recorded in this study, displaying intense transitions to the empty molecular orbitals both below and above the S 2p ionization potential (IP) and weak transitions to the Rydberg orbitals. The S 2p photoabsorption spectra of SF₆ and SF₅CF₃ have been calculated using time-dependent density functional theory, whereby the spin–orbit coupling was included for the transitions below the S 2p IP. The agreement between experiment and theory is good for both molecules, which allows us to assign the main S 2p absorption features in SF₅CF₃.     

TEA CO2-Laser Induced SF6 + Ba Beam-Surface Ionization

A TEA CO₂-laser induced SF₆ + Ba beam-surface ionization process has been studied when vibrational excitation of SF₆ molecules was carried out at (and near) the polished surface of the electrically heated up to 675 K polycristalline Ba. Electron emission and negative molecular ion signal were detected. The dependence of the molecular ion signal on laser fluence and frequency (on SF₆ molecular absorption) as well as on the SF₆ gas pressure in the nozzle were studied. The results reveal a nonlinear, probably multiphoton character of the molecular ion formation and a clear vibrational selectivity i.e. vibrational enhancement, of the SF₆ + Ba beam-surface ionization process. Possible mechanisms of the negative molecular ion formation in the IR laser induced SF₆ + Ba beam-surface ionization process are discussed.     

Molecular frame distortion and molecular pair polarizability

The contribution of frame distortion to the collision-induced polarizability of the isotropic molecules CH₄, CF₄, CCl₄ and SF₆ is estimated and found to be negligible     

Theoretical study on platinabenzene and mono- and difluorinated platinabenzenes: Structure, properties, and aromaticity

The electronic structures and properties of the platinabenzene and mono- and difluorinated platinabenzenes isomers have been investigated using hybrid density functional B3LYP theory. Basic measures of aromatic character were derived from structure, molecular orbital, and nuclear independent chemical shift (NICS). An energetic criterion suggests that ortho isomer of monofluorinated and F15 isomer of difluorinated platinabenzenes enjoy conspicuous stabilization. The polarizability and molecular orbital analysis are compatible with this result. NICS values calculated at several points above the ring center fail to give the result consistent with that based on relative energy, polarizability, and molecular orbital analysis. The atoms in molecules analysis indicates a correlation between NICS (1.0) and the electron density of the ring critical point (ρ_rcp) in monofluorinated platinabenzenes. There is a similar correlation in difluorinated platinabenzenes (except for F12 and F24 isomers) between NICS (0.5) and ρ_rcp.     

A theoretical study on electronic structure and structure–activity properties of novel drug precursor 6‐acylbenzothiazolon derivatives

In this work, electronic properties and structure–activity relationship (SAR) parameters of 20 novel drug precursor 6‐acylbenzothiazolon derivatives with analgesic activity have been investigated theoretically by performing Austin Model‐1 (AM1) and DFT‐B3LYP/6‐31G (d) calculations with the aim to correlate the properties of each substance—particularly electronic properties and SAR parameters—with the biological interactions that are linked to their pharmacological effects. Their molecular properties were related to the biological activity of these drug precursor molecules. The relationship between octanol–water partition coefficient (log P) and each of the SAR parameters [E_LUMO–HOMO, molecular volume (V_m), ionization potential (IP), electron affinity, electronegativity (χ), chemical hardness (η), chemical softness (S), electrophilic index (ω), and molar refractivity] present linear correlation except for IP and χ. This result suggests that there are future prospects for designing or developing new drugs based on the correlation between the theoretically calculated parameters. According to AM1 calculation, the values of heat of formation of 6‐acylbenzothiazolon derivatives are negative (exothermic), which shows that these molecules are thermodynamically stable. E_LUMO–HOMO energy levels of the studied molecules are 4–5 eV, which also indicate that they are kinetically unstable. © 2011 Wiley Periodicals, Inc. Int J Quantum Chem, 2011     

A molecular orbital study of bond energies in compounds of sulfur and fluorine

CNDO/2 molecular orbital theory is employed in a study of the binding energies of the molecules SF, SF₂, SF₄, SF₆, their cations and anions, and of the molecules SSF₂, FSSF and S₂F₁₀. Computed energies, when rescaled according to energy partitioning concepts, compare favorably with available experimental data. Ionization energies and electron affinities are calculated for SF, SF₂, SF₄ and SF₆.

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Zusammenfassung Mit Hilfe der CNDO/2 Theorie werden die Bindungsenergien der SF, SF₂, SF₄ und SF₆ Moleküle, von deren positiven und negativen Ionen und von SSF₂, FSSF und S₂F₁₀ berechnet. Die berechneten Energien stimmen gut mit experimentellen Daten überein, wenn sie nach Energieaufteilungsprinzipien wiederberechnet werden. Ferner werden die Ionisierungsenergien und Elektronenaffinitäten für SF, SF₂, SF₄ und SF₆ angegeben.

     

Selective Dissociation of Sulfur Hexafluoride by Intense CO2 Laser Radiation in Pulsed Gas Dynamic Flow

Isotopically selective IR multiphoton dissociation (MPD) of SF₆ in a pulsed gas dynamic flow was studied. The dependence of the yield of the product SF₄ on the frequency of CO₂ laser radiation exciting SF₆ molecules was obtained. The ³⁴S enrichment coefficient in SF₄ was measured. The enrichment factor was found to agree well with the value predicted from comparison of spectral dependences for the SF₄ yield from ³²SF₆ and ³⁴SF₆. The obtained results are compared with the data on SF₆ dissociation in a low-temperature cell and in a molecular beam.     

Electron impact ionization of CCl4 and SF6 embedded in superfluid helium droplets

Electron impact ionization of helium nano-droplets containing several 10⁴ He atoms and doped with CCl₄ or SF₆ molecules is studied with high-mass resolution. The mass spectra show significant clustering of CCl₄ molecules, less so for SF₆ under our experimental conditions. Positive ion efficiency curves as a function of electron energy indicate complete immersion of the molecules inside the helium droplets in both cases. For CCl₄ we observe the molecular parent cation CCl₄⁺ that preferentially is formed via Penning ionization upon collisions with He*. In contrast, no parent cation SF₆⁺ is seen for He droplets doped with SF₆. The fragmentation patterns for both molecules embedded in He are compared with gas phase studies. Ionization via electron transfer to He⁺ forms highly excited ions that cannot be stabilized by the surrounding He droplet. Besides the atomic fragments F⁺ and Cl⁺ several molecular fragment cations are observed with He atoms attached.     

Theoretical investigation on structures, electronic spectra and nonlinear optical properties of gold compounds [X-“Au(PMe3)”2]

The structures, electronic spectra, polarizability and third-order nonlinear optical properties of six gold compounds [X-“Au(PMe₃)”₂] were investigated by density functional theory (DFT) B3LYP and BhandHLYP methods. It was found that the calculation methods and basis set are rational for the object of study, and molecular structures change slightly when PPh₃ is replaced by PMe₃. The spatial effects of the bridging section have a significant influence on the polarizability, but indistinctive to the third-order nonlinear optical (NLO) coefficient. As a result of the conjugated effect in different compounds, the third-order polarizability of molecule 1a is the smallest, while that of molecule 2a is the largest. Au has donor ability in molecule 1a but acceptor ability in molecules 2a–6a by analyzing the electronic spectra and frontier molecular orbitals constitute maximal absorption, which indicates the contribution of Au to NLO properties in the six molecules is different.     

Modeling the H bond donor strength of ?OH, ?NH,and ?CH sites by local molecular parameters

A quantum chemical model is introduced to predict the H‐bond donor strength of monofunctional organic compounds from their ground‐state electronic properties. The model covers ? OH, ? NH, and ? CH as H‐bond donor sites and was calibrated with experimental values for the Abraham H‐bond donor strength parameter A using the ab initio and density functional theory levels HF/6‐31G** and B3LYP/6‐31G**. Starting with the Morokuma analysis of hydrogen bonding, the electrostatic (ES), polarizability (PL), and charge transfer (CT) components were quantified employing local molecular parameters. With hydrogen net atomic charges calculated from both natural population analysis and the ES potential scheme, the ES term turned out to provide only marginal contributions to the Abraham parameter A, except for weak hydrogen bonds associated with acidic ? CH sites. Accordingly, A is governed by PL and CT contributions. The PL component was characterized through a new measure of the local molecular hardness at hydrogen, η(H), which in turn was quantified through empirically defined site‐specific effective donor and acceptor energies, EE_occ and EE_vac. The latter parameter was also used to address the CT contribution to A. With an initial training set of 77 compounds, HF/6‐31G** yielded a squared correlation coefficient, r², of 0.91. Essentially identical statistics were achieved for a separate test set of 429 compounds and for the recalibrated model when using all 506 compounds. B3LYP/6‐31G** yielded slightly inferior statistics. The discussion includes subset statistics for compounds containing ? OH, ? NH, and active ? CH sites and a nonlinear model extension with slightly improved statistics (r² = 0.92). © 2008 Wiley Periodicals, Inc. J Comput Chem 2009     

The frequency,fluence, and pressure dependence of the absorption of pulsed CO2-laser radiation by SF6 at 140 K

We report measurements of absorption of pulsed CO₂ laser radiation by SF₆ at 140 K. These measurements cover a broad range of fluence (10^?6 to 0.8 J/cm²), SF₆ gas density (2 × 10¹⁵ to 6 × 10¹⁶ cm^?3), and frequency (six CO₂-laser frequencies within the SF₆ v₃ band). We employ two methods of data reduction including one that gives a simple phenomenological function of the three principal independent variables. We conclude that at low fluence a small fraction of the SF₆ molecules absorb the laser radiation and that collisions and higher fluence both increase that fraction. At higher fluence absorption by vibrationally excited molecules becomes increasingly important.     

Chalkogenfluoride in niedrigen Oxydationsstufen. IV. Darstellung und Charakterisierung von reinem S2F4

Lower Chalcogen Fluorides. IV. Preparation and Characterization of Pure S₂F₄ Reactions of S and COS, respectively, with elemental fluorine in a metal high vacuum apparatus give a mixture of SF₆, SF₄, S?SF₂, and S₂F₄. At ? 78°C S₂F₄ can be freed from impurities and isolated in a pure state. Molecular weight, density, melting point, vapour pressure, boiling point, IR, UV-, ¹⁹F-NMR, and mass spectra are presented.     

Theoretical investigations on electronics structure and chemical bonding on iridathiabenzene and iridaoxabenzene

The electronic structure and properties of the iridathiabenzene and iridaoxabenzene isomers have been investigated using the hybrid density functional mpw1pw91 theory. The energetic aspect shows that trans-ortho-isomer is the most stable isomer. This is compatible with principles of minimum energy and minimum polarizability. Molecular orbital analysis shows a linear correlation between hardness and anisotropic polarizability values for Iridathiabenzene and iridaoxabenzene isomers. The structural and natural bond analysis (NBO) results illustrate electronic delocalization in these rings. Also, the study of non linear optical properties of these molecules indicate a good correlation between β_tot and E(HOMO) for iridathiabenzene. The results from natural bond orbital (NBO) analysis have provided insights into Ir—ligand, P—H_apical and P—H_basal bonding.     

Dynamics of the barium-molecule system within large argon clusters

The effects of adding molecules on the LIF at 540 nm of a barium atom at the surface of an argon cluster (average size 420) has been investigated. We showed that molecules like ethanol,n-hexane and O₂ from stable complexes with ground state barium. In the case of molecules like N₂, CH₄ and SF₆, the collisional quenching of solvated Ba(¹ P) is observed. The large quenching rates obtained are interpreted by a surface mobility of the collisional partners. Moreover, we showed that this collisional quenching leads to the ejection of free Ba(³ P ₁).