Abstract

The properties of nine binary Lewis acid-base complexes, formed between boron trifluoride, on the one hand, and the carbon dioxide analogues XCY (X, Y = O, S, Se) on the other, have been investigated by means of ab initio calculations. The properties of most interest are the structures, the interaction energies, the vibrational spectra and the natural orbital population changes. The structures of the complexes bound through either a sulphur or a selenium atom are remarkably similar, and feature a FB … XC fragment in a trans arrangement, with FB … X and B … XC angles close to 90°. The adducts bound through oxygen have quite different structures, with a B … OC angle close to 150° in the case of BF3·OCO and with linear B … OCS and B … OCSe moieties in the other two cases. The binding energies of all nine complexes span a very narrow range, and are all less than 10 kJ mol−1. The changes of the intramolecular BF, XC and CY bond lengths are small, but they vary in a systematic way with the strength of interaction. The wavenumber shifts of the modes of the BF3 and XCY fragments are also fairly insignificant, except for the symmetric bending mode of the BF3 molecule, where the shifts are found to be in the range from −20 to −40 cm−1. The similarities and differences in the properties of the three families of adducts have been rationalized by reference to the redistribution of the natural orbital populations resulting from complex formation.

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