Structure of trimethyldioxorhenium, (CH3)(3)ReO2 as studied by spectroscopic methods, gas electron diffraction, and density functional theory calculations. Tilted methyl groups: Agostic C-H center dot center dot center dot Minteractions or bent M-C bonds?
A. Haaland et al., Structure of trimethyldioxorhenium, (CH3)(3)ReO2 as studied by spectroscopic methods, gas electron diffraction, and density functional theory calculations. Tilted methyl groups: Agostic C-H center dot center dot center dot Minteractions or bent M-C bonds?, ORGANOMETAL, 19(1), 2000, pp. 22-29
The structural model of the trimethyldioxorhenium molecule, Me3ReO2 (1), ha
s been revised on the basis of analysis of its H-1, C-13, and O-17 NMR and
vibrational spectra and of its gas electron diffraction (GED) pattern. The
results are consistent with the molecular symmetry C-s; in the new model bo
th oxo ligands together with one methyl group are located in the equatorial
plane of a distorted trigonal bipyramid. Structure optimization by density
functional theory (DFT) calculations and least-squares refinement to the G
ED data yield the valence angles (calc/expt; eq = equatorial; ax = axial; a
v = average) angle CeqReO = 118.0/118.5(10)degrees and angle CeqReCax = 74.
3/73.5(11)degrees. The pseudoaxial Re-C bond distance is found to be shorte
r than the equatorial one, viz., Re-C-ax = 2.130/2.122(6) Angstrom versus R
e-C-eq = 2.193/ 2.199(22) Angstrom, and Re=O-av = 1.739/1.703(3) Angstrom.
It is suggested that the distortion from trigonal bipyramidal to edge-bridg
ed tetrahedral coordination geometry is driven by the need for the axial C
atoms to achieve optimal overlap with both the d(z)2 and d(yz) orbitals on
the Re atom. The DFT calculations indicate that the axial methyl groups are
tilted in such a manner that the angle ReCH valence angles in the ReC3 pla
ne are reduced to 100.8 degrees. It is suggested that this tilting is due i
n part to bent Re-C-ax bonds and in part to weak C-H ... Re agostic interac
tions.