Conspectus
One of the
major challenges facing organic synthesis in the 21st
century is the utilization of abundantly available feedstock chemicals
for fine chemical synthesis. Regio- and enantioselective union of
easily accessible 1,3-dienes and other feedstocks like ethylene, alkyl
acrylates, and aldehydes can provide valuable building blocks adorned
with latent functionalities for further synthetic elaboration. Through
an approach that relies on mechanistic insights and systematic examination
of ligand and counterion effects, we developed an efficient cobalt-based
catalytic system [(P∼P)CoX2/Me3Al] (P∼P = bisphosphine) to effect the
first enantioselective heterodimerization of several types of 1,3-dienes
with ethylene. In addition to simple cyclic and acyclic dienes, siloxy-1,3-dienes
participate in this reaction, giving highly functionalized, nearly
enantiopure silyl enolates, which can be used for subsequent C–C
and C–X bond-forming reactions. As our understanding of the
mechanism of this reaction improved, our attention was drawn to more
challenging partners like alkyl acrylates (one of the largest volume
feedstocks) as the olefin partners instead of ethylene. Prompted by
the intrinsic limitations of using aluminum alkyls as the activators
for this reaction, we explored the fundamental chemistry of the lesser
known (P∼P)Co(I)X species and discovered
that in the presence of halide sequestering agents, such as sodium
tetrakis[3,5-bis(trifluoromethyl)phenyl]borate (NaBARF) or (C6F5)3B, certain chiral bisphosphine complexes
are superb catalysts for regio- and enantioselective heterodimerization
of 1,3-dienes and alkyl acrylates. We have since found that these
cationic Co(I) catalysts, most conveniently prepared in situ by reduction
of the corresponding cobalt(II) halide complexes by zinc in the presence
of NaBARF, promote enantioselective [2 + 2]-cycloaddition between
alkynes and an astonishing variety of alkenyl derivatives to give
highly functionalized cyclobutenes. In reactions between 1,3-enynes
and ethylene, the [2 + 2]-cycloaddition between the alkyne and ethylene
is followed by a 1,4-addition of ethylene in a tandem fashion to give
nearly enantiopure cyclobutanes with an all-carbon quaternary center,
giving a set of molecules that maps well into many medicinally relevant
compounds. In another application, we find that the cationic Co(I)-catalysts
promote highly selective hydroacylation and 1,2-hydroboration of prochiral
1,3-dienes. Further, we find that a cationic Co(I)-catalyst promotes
cycloisomerization followed by hydroalkenylation of 1,6-enynes to
produce highly functionalized carbo- and heterocyclic compounds. Surprisingly
the regioselectivity of the alkene addition depends on whether it
is a simple alkene or an acrylate, and the acrylate addition produces
an uncommon Z-adduct. This Account will provide a
summary of the enabling basic discoveries and the attendant developments
that led to the unique cationic Co(I)-complexes as catalysts for disparate
C–C and C–B bond-forming reactions. It...
