Issue 23, 2019

Computational studies of ene reactions between aminoborane (F3C)2B[double bond, length as m-dash]N(CH3)2 and substituted propenes: additive effects on barriers and reaction energies

Abstract

Systematic computational studies of concerted pericyclic ene-type reactions between aminoborane (F3C)2B[double bond, length as m-dash]N(CH3)2, 1, and substituted propenes (R1a)(R1e)C[double bond, length as m-dash]C(R2)–C(R3a)(R3e)H (R = Me, CF3, F; a = axial position in transition state, e = equatorial position in transition state) show that in all cases but one the reactions are exothermic. The reactions proceed through six-membered cyclic envelope-like transition states except in the case of 1 + C3H(CF3)5. The data allow isolation of substitutional effects on barrier heights; the effects appear to be additive in all cases. Substitution at positions 1a, 1e, and 3a increases barriers, while substitution at positions 2 and 3e has variable impacts. The former observation is ascribed to steric crowding in the transition states, and is particularly prevalent for substitution at positions 1a and 1e. Substitution at position 2 lowers barriers for R = Me, F, possibly due to electronic demands, while raising them for R = CF3 because of 1,3-diaxial repulsions between boron- and carbon-bound CF3 groups. Substitution at position 3e has little impact on the barriers for R = Me, CF3, but significantly raises them for R = F. This seems to arise from charge effects on the position of the transition states.

Graphical abstract: Computational studies of ene reactions between aminoborane (F3C)2B [[double bond, length as m-dash]] N(CH3)2 and substituted propenes: additive effects on barriers and reaction energies

Supplementary files

Article information

Article type
Paper
Submitted
28 मार्च 2019
Accepted
07 मई 2019
First published
13 मई 2019

Dalton Trans., 2019,48, 8161-8174

Computational studies of ene reactions between aminoborane (F3C)2B[double bond, length as m-dash]N(CH3)2 and substituted propenes: additive effects on barriers and reaction energies

A. L. Gille, S. E. Hammer, J. M. Lafferty, K. R. Lawson, J. R. Gustafson, B. C. Dutmer and T. M. Gilbert, Dalton Trans., 2019, 48, 8161 DOI: 10.1039/C9DT01333D

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