Theoretical molecular design of hexasilabenzene analogues aiming for the thermodynamic and kinetic stabilization

Comparison of group 14 elements in sp3 and sp2 environment by fragment structure energy analysis

To explore the characteristics of group 14 elements in sp³ and sp² hybrid environments systematically, the concept of fragment structure energy (FSE) was proposed through ab initio molecular orbital method. A fragment in this study means a building block of molecular structure and the energy of each kind of fragments (FSE) is obtained from the total electronic energy of different size of model compounds by just a simple algebraic method. The model compounds are the hydrogen-terminated diamond and graphene analogs as the typical compounds in the ideal sp³ - and sp² -environment, respectively. As a result, the sp³ environment was found to be more stable than the sp² for all the group 14 elements (C-Pb) in the ideal hybrid environment. Furthermore, a mixing effect of carbon and heavier group 14 elements (E = Si, Ge, Sn, and Pb) was investigated by comparing the E/C-alternately mixed- and the pure FSEs.

The planarity of heteroatom analogues of benzene: Energy component analysis and the planarization of hexasilabenzene

There are various nonplanar heteroatom analogues of benzene-cyclic 6π electron systems-and among them, hexasilabenzene (Si₆ H₆ ) is well known as a typical example. To determine the factors that control their planarity, quantum chemical calculations and an energy component analysis were performed. The results show that the energy components mainly controlling the planarity of benzene and hexasilabenzene are different. For hexasilabenzene, electron repulsion energy was found to be significantly important for the planarity. The application of the pseudo Jahn-Teller effect and the Carter-Goddard-Malrieu-Trinquier model for the interpretation of the planarity of the benzene analogues was also investigated. Furthermore, based on the quantitative results, it was revealed that the planarization of hexasilabenzene is realized by introducing substituents with π-accepting ability, such as the boryl group, that bring about a reduction of the π-electron repulsion on the silicon skeleton. © 2018 Wiley Periodicals, Inc.

Designing the Backbone of Hexasilabenzene Derivatives with a High Unimolecular Kinetic Stability

It is an important subject to theoretically predict the kinetic stability of transient species. In this study, we have studied the kinetic stability of hexasilabenzene Si₆ H₆ and its derivatives, that is, decasilanaphthalene Si₁₀ H₈ and Li-substituted hexasilabenzene Si₆ Li₆ , theoretically by the artificial force induced reaction (AFIR) method combined with the rate constant matrix contraction (RCMC) method. Molecular design was further conducted to extend the unimolecular lifetime of hexasilabenzene derivatives. Although both Si₁₀ H₈ and Si₆ Li₆ were shown to possess shorter lifetimes than Si₆ H₆ , we found that the lifetimes of Si₆ Li₆ changed depending on arrangements of Li atoms around the monocyclic Si₆ backbone. Based on this knowledge, we found that a compound of an atomic composition Si₆ H₄ Li₂ with a planar, monocyclic Si₆ backbone has a relatively long unimolecular lifetime. Moreover, substitution of the two Li atoms by Na atoms further increased the lifetime.