Comparative Reactivity of Zr– and Pd–Alkyl
Complexes with Carbon Dioxide
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Abstract
Structure/reactivity
trends and DFT studies reveal mechanistic
differences and parallels for the carboxylation of Zr and Pd alkyls.
CO<sub>2</sub> reacts with Cp<sub>2</sub>ZrMe(C<sub>6</sub>D<sub>5</sub>Cl)<sup>+</sup> >10<sup>4</sup> faster than with Cp<sub>2</sub>ZrMe<sub>2</sub>, yielding monoacetate products in both cases. These
reactions
proceed by insertion mechanisms in which Zr- - -O interactions
activate the CO<sub>2</sub>. In contrast, CO<sub>2</sub> reacts readily
with [(PO-<sup>i</sup>Pr)PdMe<sub>2</sub>]<sup>−</sup> (PO-<sup>i</sup>Pr<sup>–</sup> = 2-P<sup>i</sup>Pr<sub>2</sub>-4-Me-C<sub>6</sub>H<sub>3</sub>SO<sub>3</sub><sup>–</sup>) to yield [(PO-<sup>i</sup>Pr)PdMe(OAc)]<sup>−</sup> but not with (PO-<sup>i</sup>Pr)PdMe(L) species. Carboxylation of [(PO-<sup>i</sup>Pr)PdMe<sub>2</sub>]<sup>−</sup> occurs by direct S<sub>E</sub>2 attack
of CO<sub>2</sub> at the Pd–Me<sub><i>trans</i>‑to‑P</sub> group, and the nucleophilicity of the Pd–Me group controls
the reactivity. However, the S<sub>E</sub>2 process is accelerated
by a Li<sup>+</sup>- - -OCO interaction when Li<sup>+</sup> is present
