A series of copper(I)
complexes bearing electron-deficient β-diketiminate ligands
have been prepared. The study includes [{{ArNC(CR3)}2CH}Cu(η2-toluene)n] (Ar = Mes,
R = F, n = 0.5, [1
2
·tol]; Ar = C6F5, R
= Me, n = 1, [2·tol]; Ar = 2,6-Cl2C6H3, R = H, n = 0.5,
[3
2
·tol]).
Reactions of [1–3
n
·tol] with boranes, alanes,
a zinc hydride, a magnesium hydride, and a calcium hydride generate
the corresponding σ complexes ([1–3·B], [3·B′], [3·Al], [3·Al′], [1–3·Zn], [1·Mg], and [1·Ca]). These species all
form reversibly, being in equilibrium with the arene solvates in solution.
With the exception of the calcium complex, the complexes have all
been characterized by single-crystal X-ray diffraction studies. In
solution, the σ-hydride of the aluminum, zinc, magnesium, and
calcium derivatives resonates between −0.12 and −1.77
ppm (C6D6 or toluene-d
8, 193–298 K). For the σ-borane complexes, the
hydrides are observed as a single resonance between 2 and 3.5 ppm
(C6D6, 298 K) and bridging and terminal hydrides
rapidly exchange on the NMR time scale even at 193 K. Quantification
of the solution dynamics by van’t Hoff analysis yields expectedly
small values of ΔH° and negative values
of ΔS° consistent with weak binding and
a reversible process that does not involve aggregation of the copper
species. The donor–acceptor complexes can be rationalized in
terms of the Dewar–Chatt–Duncanson model. Density functional
theory calculations show that the donation of σ-M–H (or
E–H) electrons into the 4s-based orbital (LUMO or LUMO+1) of
the copper fragment is accompanied by weak back-donation from a d
xz
-based orbital (HOMO or HOMO–1) into
the σ*-M–H (or E–H) orbital.
