posted on 2017-06-06, 20:31authored byMatthew
D. Ryan, Ryan M. Pearson, Tracy A. French, Garret M. Miyake
Organic photoredox
catalysts have been shown to operate organocatalyzed
atom transfer radical polymerizations (O-ATRP) using visible light
as the driving force. In this work, the effect of light intensity
from white LEDs was evaluated as an influential factor in control
over the polymerization and the production of well-defined polymers.
We posit the irradiation conditions control the concentrations of
various catalyst states necessary to mediate a controlled radical
polymerization. Systematic dimming of white LEDs allowed for consideration
of the role of light intensity on the polymerization performance.
The general effects of decreased irradiation intensity in photoinduced
O-ATRP were investigated through comparing two different organic photoredox
catalysts: perylene and an 3,7-di(4-biphenyl) 1-naphthalene-10-phenoxazine.
Previous computational efforts have investigated catalyst photophysical
and electrochemical characteristics, but the broad and complex effects
of varied irradiation intensity as an experimental variable on the
mechanism of O-ATRP have not been explored. This work revealed that
perylene requires more stringent irradiation conditions to achieve
controlled polymer molecular weight growth and produce polymers with
dispersities <1.50. In contrast, the 3,7-di(4-biphenyl) 1-naphthalene-10-phenoxazine
is more robust, achieving linear polymer molecular weight growth under
relative irradiation intensity as low as 25%, to produce polymers
with dispersities <1.50. This finding is significant, as the discovery
of highly robust catalysts is necessary to allow for the adoption
of successful O-ATRP in a wide scope of conditions, including those
which necessitate low light intensity irradiation.