posted on 2021-09-02, 20:31authored byDonghyun Kim, Juan Felipe Franco-Gonzalez, Igor Zozoulenko
Poly(3,4-ethylenedioxythiophene)
(PEDOT) is one of the most important
conductive polymers utilized in a variety of applications in organic
electronics and bioelectronics and energy storage. PEDOT chains are
believed to be rather short, but detailed knowledge of their length
is missing because of the challenges in its experimental determination
due to insolubility of PEDOT films. Here, we report a molecular dynamics
(MD) study of in situ oxidative chemical polymerization and simultaneous
crystallization of molecularly doped PEDOT focusing on the determination
of its chain lengths at different polymerization temperatures. We
find the average chain length to be 6, 7, and 11 monomers for 298,
323 and 373 K, respectively. At the same time, the length distribution
is rather broad, for example, between 2 and 16 monomer units for T = 323 K. We demonstrate that the limiting factor determining
the chain length is the diffusivity of the reactants (PEDOT monomers
and oligomers). We also study the polymer film formation during solvent
evaporation, and we find that although crystallization starts and
proceeds already during the polymerization and doping phases, it mostly
occurs during the evaporation phase. Finally, we believe that our
results providing the oligomer chain length and polymerization and
crystallization mechanisms obtained by means of MD “computational
microscopy” provide an important insight into the morphology
of PEDOT that cannot be obtained by other means.