ConspectusThe important
role of transition metal-catalyzed cross-coupling in expanding the
frontiers of accessible chemical territory is unquestionable. Despite
empowering chemists with Herculean capabilities in complex molecule
construction, contemporary protocols are not without their Achilles’
heel: Csp3–Csp2/sp3 coupling. The underlying challenge in sp3 cross-couplings is 2-fold: (i) methods employing conventional, bench-stable
precursors are universally reliant on extreme reaction conditions
because of the high activation barrier of transmetalation; (ii) circumvention
of this barrier invariably relies on use of more reactive precursors,
thereby sacrificing functional group tolerance, operational simplicity,
and broad applicability. Despite the ubiquity of this problem, the
nature of the transmetalation step has remained unchanged from the
seminal reports of Negishi, Suzuki, Kumada, and Stille, thus suggesting
that the challenges in Csp3–Csp2/sp3 coupling result from inherent mechanistic
constraints in the traditional cross-coupling paradigm. Rather than
submitting to the limitations of this conventional approach, we envisioned
that a process rooted in single-electron reactivity could furnish
the same key metalated intermediate posited in two-electron transmetalation,
while demonstrating entirely complementary reactivity patterns.Inspired by literature reports on the susceptibility of organoboron
reagents toward photochemical, single-electron oxidative fragmentation,
realization of a conceptually novel open shell transmetalation framework
was achieved in the facile coupling of benzylic trifluoroborates with
aryl halides via cooperative visible-light activated photoredox and
Ni cross-coupling catalysis. Following this seminal study, we disclosed
a suite of protocols for the cross-coupling of secondary alkyl, α-alkoxy,
α-amino, and α-trifluoromethylbenzyltrifluoroborates.
Furthermore, the selective cross-coupling of Csp3 organoboron moieties in the presence of Csp2 organoboron motifs was also demonstrated, highlighting the nuances
of this approach to transmetalation. Computational modeling of the
reaction mechanism uncovered useful details about the intermediates
and transition-state structures involved in the nickel catalytic cycle.
Most notably, a unique dynamic kinetic resolution process, characterized
by radical homolysis/recombination equilibrium of a NiIII intermediate, was discovered. This process was ultimately found
to be responsible for stereoselectivity in an enantioselective variant
of these cross-couplings.Prompted by the intrinsic limitations
of organotrifluoroborates, we sought other radical feedstocks and
quickly identified alkylbis(catecholato)silicates as viable radical
precursors for Ni/photoredox dual catalysis. These hypervalent silicate
species have several notable benefits, including more favorable redox
potentials that allow extension to primary alkyl systems incorporating
unprotected amines as well as compatibility with less expensive Ru-based
photocatalysts. Additionally, these reagent...
