Dm. Schuster et Jl. Templeton, E Z-ISOMERIZATION DYNAMICS IN MOLYBDENUM AND TUNGSTEN ETA(1)-KETONE COMPLEXES/, Organometallics, 17(13), 1998, pp. 2707-2715
A series of tungsten(II) and molybdenum(II) iodide complexes of the ty
pe {TP}M(CO)(RC=CR')I ({Tp} = Tp, Tp'; M = Mo, W; R, R' = Ph, Me) (5a-
g) have been synthesized by utilizing hydridotris(1-pyrazolyl)borate (
Tp) and hydridotris(3,5-dimethylpyrazolyl)borate (Tp') ligands and 1-p
henyl-1-propyne, 2-butyne, and diphenylacetylene alkynes. Reacting the
iodide complexes 5a-g with either LiCuMe2 or Me2Mg formed the corresp
onding methyl complexes {Tp}M(CO)(RC=CR')Me (7a-g), which serve as Lew
is acid precursors in these systems. Protonation of the methyl complex
es with HBAr'(4).2OEt(2) (BAr'(4) = tetrakis[3,5-bis(trifluoromethyl)p
henyl]borate), loss of methane, and addition of a ketone (acetone, 2-b
utanone, 3-methyl-2-butanone, acetophenone, or pinacolone) gave the et
a(1)-ketone complexes. The ketone complexes exhibit different conforma
tional preferences about the M-O bond. The E/Z-isomerization barriers
of the ketone complexes were calculated using coalescence temperatures
from low-temperature H-1 NMR spectra. Differences in E/Z-isomerizatio
n barriers between Tp and Tp' tungsten and molybdenum systems are anal
yzed in terms of an isomerization mechanism involving a linear M <-- O
= C transition state. The vacant d pi orbital of the d(4) metal and t
he versatility of the alkyne pi perpendicular to donation into the d p
i-orbital enhances accessibility of the linear transition state for E/
Z-isomerization.