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The Importance of Strain (Preorganization) in Beryllium Bonds

In order to explore the angular strain role on the ability of Be to form strong beryllium bonds, a theoretical study of the complexes of four beryllium derivatives of ortho closo-carboranes with eight molecules (CO, N(2), NCH, CNH, OH(2), SH(2), NH(3), and PH(3)) acting as Lewis bases has been carri...

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Detalles Bibliográficos
Autores principales: Alkorta, Ibon, Elguero, José, Oliva-Enrich, Josep M., Yáñez, Manuel, Mó, Otilia, Montero-Campillo, M. Merced
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2020
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7763456/
https://www.ncbi.nlm.nih.gov/pubmed/33322617
http://dx.doi.org/10.3390/molecules25245876
Descripción
Sumario:In order to explore the angular strain role on the ability of Be to form strong beryllium bonds, a theoretical study of the complexes of four beryllium derivatives of ortho closo-carboranes with eight molecules (CO, N(2), NCH, CNH, OH(2), SH(2), NH(3), and PH(3)) acting as Lewis bases has been carried out at the G4 computational level. The results for these complexes, which contain besides Be other electron-deficient elements, such as B, have been compared with the analogous ones formed by three beryllium salts (BeCl(2), CO(3)Be and SO(4)Be) with the same set of Lewis bases. The results show the presence of large and positive values of the electrostatic potential associated to the beryllium atoms in the isolated four beryllium derivatives of ortho-carboranes, evidencing an intrinsically strong acidic nature. In addition, the LUMO orbital in these systems is also associated to the beryllium atom. These features led to short intermolecular distances and large dissociation energies in the complexes of the beryllium derivatives of ortho-carboranes with the Lewis bases. Notably, as a consequence of the special framework provided by the ortho-carboranes, some of these dissociation energies are larger than the corresponding beryllium bonds in the already strongly bound SO(4)Be complexes, in particular for N(2) and CO bases. The localized molecular orbital energy decomposition analysis (LMOEDA) shows that among the attractive terms associated with the dissociation energy, the electrostatic term is the most important one, except for the complexes with the two previously mentioned weakest bases (N(2) and CO), where the polarization term dominates. Hence, these results contribute to further confirm the importance of bending on the beryllium environment leading to strong interactions through the formation of beryllium bonds.