ConspectusBinding of molecules in molecular cages based on self-assembled
concave building blocks has been of great interest to scientists for
decades. The binding of static molecular fragments inside cage-like
molecular structures is generally based on complementarity of host
and guest in terms of shape and interactions. The encapsulation of
homogeneous catalysts in molecular cages is of interest as activity,
selectivity, and stability can be controlled by the cage as second
coordination sphere, reminiscent of how enzymes control chemical reactivity.
Homogeneous catalysts, however, are not static guest molecules as
catalysts change in shape, charge, and polarity during the catalytic
cycle, representing the challenges involved in cage controlled catalysis.
To address these issues, we developed a new strategy that we coined
the “ligand template approach for catalyst encapsulation”.
This strategy relies on ligand building blocks that contain multiple
orthogonal binding sites: the central ligand (mostly phosphorus) is
bound to the transition metal required for catalysis, while other
binding sites are used to construct a cage structure around the transition
metal atom through self-assembly. By design, the catalyst is inside
the capsule during the catalytic cycle, as the central ligand is coordinated
to the catalyst. As the approach is based on a self-assembly process
of building blocks, the catalyst properties can be easily modulated
by modification of building blocks involved.In this Account,
we elaborate on template ligand strategies for
single catalyst encapsulation, based on divergent ligand templates
and the extension to nanospheres with multiple metal complexes, which
are formed by assembly of convergent ligand templates. Using the mononuclear
approach, a variety of encapsulated catalysts can be generated, which
have led to highly (enantio)selective hydroformylation reactions for
encapsulated rhodium atoms. Besides the successes of encapsulated
rhodium catalysts in hydroformylation, mononuclear ligand template
capsules have been applied in asymmetric hydrogenation, the Heck reaction,
copolymerization, gold catalyzed cyclization reactions, and hydrosilylation
reactions. By changing the capsule building blocks the electronic
and steric properties around the transition metal atom have successfully
been modified, which translates to changes in catalyst properties.
Using the convergent ligand templates, nanospheres have been generated
with up to 24 complexes inside the sphere, leading to very high local
concentrations of the transition metal. The effect of local concentrations
was explored in gold catalyzed cyclization reactions and ruthenium
catalyzed water oxidation, and for both reactions, spectacular reaction
rate enhancements have been observed. This Account shows that the
template ligand approach to provide catalyst in well-defined specific
environments is very versatile and leads to catalyst properties that
are not achievable with traditional approaches.
