1 research outputs found
Indium Catalysts for Low-Pressure CO<sub>2</sub>/Epoxide Ring-Opening Copolymerization: Evidence for a Mononuclear Mechanism?
The alternating copolymerization
of CO<sub>2</sub>/epoxides is
a useful means to incorporate high levels of carbon dioxide into polymers.
The reaction is generally proposed to occur by bimetallic or bicomponent
pathways. Here, the first indium catalysts are presented, which are
proposed to operate by a distinct mononuclear pathway. The most active
and selective catalysts are phosphasalen complexes, which feature
ligands comprising two iminophosphoranes linked to sterically hindered <i>ortho</i>-phenolates. The catalysts are active at 1 bar pressure
of carbon dioxide and are most effective without any cocatalyst. They
show low-pressure activity (1 bar pressure) and yield polymer with
high carbonate linkage selectivity (>99%) and isoselectivity (<i>P</i><sub>m</sub> > 70%). Using these complexes, it is also
possible to isolate and characterize key catalytic intermediates,
including the propagating indium alkoxide and carbonate complexes
that are rarely studied. The catalysts are mononuclear under polymerization
conditions, and the key intermediates show different coordination
geometries: the alkoxide complex is pentacoordinate, while the carbonate
is hexacoordinate. Kinetic analyses reveal a first-order dependence
on catalyst concentration and are zero-order in carbon dioxide pressure;
these findings together with in situ spectroscopic studies underpin
the mononuclear pathway. More generally, this research highlights
the future opportunity for other homogeneous catalysts, featuring
larger ionic radius metals and new ligands, to operate by mononuclear
mechanisms