posted on 2022-07-22, 08:45authored byOr Eivgi, Suzanne A. Blum
Polymer growth induces physical changes to catalyst microenvironments.
Here, these physical changes are quantified in real time and are found
to influence microscale chemical catalysis and the polymerization
rate. By developing a method to “peer into” optically
transparent living-polymer particles, simultaneous imaging of both
viscosity changes and chemical activity was achieved for the first
time with high spatiotemporal resolution through a combination of
fluorescence intensity microscopy and fluorescence lifetime imaging
microscopy techniques. Specifically, an increase in microenvironment
viscosity led to a corresponding local decrease in the catalytic molecular
ruthenium ring-opening metathesis polymerization rate, plausibly by
restricting diffusional access to active catalytic centers. Consistent
with this diffusional-access model, these viscosity changes were found
to be monomer-dependent, showing larger changes in microenvironment
viscosity in cross-linked polydicyclopentadiene compared to non-crosslinked
polynorbornene. The sensitivity and high spatial resolution of the
imaging technique revealed significant variations in microviscosities
between different particles and subparticle regions. These revealed
spatial heterogeneities would not be observable through alternative
ensemble analytical techniques that provide sample-averaged measurements.
The observed spatial heterogeneities provide a physical mechanism
for variation in catalytic chemical activity on the microscale that
may accumulate and lead to nonhomogeneous polymer properties on the
bulk scale.