Nikolai KOROTKIKH1, Gennady RAYENKO2, Vagiz SABEROV1, Оles SHVAIKA2
1Institute of Organic Chemistry of UNAS, Murmanskaya, 5, 02094 Kyiv, Ukraine 2L.M. Litvinenko Institute of Physical Organic and Coal Chemistry of UNAS, Kharkiv road, 50, 02160 Kyiv, Ukraine
DOI: https://doi.org/10.37827/ntsh.chem.2019.56.007
DIMERIZATION ENERGIES AS AN IMPORTANT FACTOR OF CARBENE STABILITY. I. IMIDAZOL-2-YLIDENES.
A review of the dimerization reactions of carbenes and methods for their studies is given. The basic types of heterocyclic carbene dimers, which have been isolated and described up today, the types of carbenes that do not undergo dimerization, dimeric biscarbenes, cyclophanic dimers and polycarbenes, are presented. The mechanism of dimers formation on the example of interaction of carbenes of different nature is determined including the cases of recyclization reactions of cyclopropenylidene derivatives. It was described the approaches to the determination of the dimerization energy via the singlet-triplet splitting energies (the approach of Carter and Goddard, Kassaee), via the enthalpies of isodesmic reactions with methane and the linear equations between the electron and steric parameters of substituents for relatively simple carbenes (Nyulaszi). The energy of dimerization (electronic and steric parameter ESP) is first used in the work to assess the stability of the complicated substituted carbenic system of imidazol-2-ylidenes. The quantum-chemical calculation results of the dimerization energies of known and new promising carbenes of a series of imidazol-2-ylidenes are estimated in this work using the DFT method (B3LYP5, 3-21G та 6-31G, RHF). The scale of influence of substituents on the stability of carbenes in a series of imidazol-2-ylidenes has been developed. For 1-tert-butyl substituted compounds, the following range of substituents is observed for the ESP: Dbp > Dipp > Mes > CPh3 > PAd2 ≈ t-C4F9 > PtBu2 > 1-Ad ≈t-Bu> NMe2> Np> NiРr2 > i–Pr > Me. For 1-benzhydryl substituted substituted the series is as follows: Dbp > Dipp > t-Bu > Mes > Me > i-Pr. For 1-methyl substituted compounds the next row is given: СPh3 > Dipp > 1-Ad > PAd2 > РtBu2 > t-Bu > Np > Dbp > Mes > NiРr2 > NMe2 > Ph > i-Pr > Me > P(i-Pr2N)2). Based on the values of the dimerization energies, conclusions are made regarding the effect of the heterocyclic nucleus on the stability of carbenes. Imidazol-2-ylidenes are among the most stable according to this property. It is shown that the steric influence of the substituents affects not only the kinetic, but also the thermodynamic stabilization of the carbenes.
Keywords: dimerization energies, heterocyclic carbenes, effect of structure.
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How to Cite
Korotkikh N., Rayenko G., Saberov V., Shvaika О. DIMERIZATION ENERGIES AS AN IMPORTANT FACTOR OF CARBENE STABILITY. I. IMIDAZOL-2-YLIDENES. Proc. Shevchenko Sci. Soc. Chem. Sci. 2019 Vol. LVI. P. 7-22.
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