posted on 2016-05-17, 00:00authored bySooraj Kunnikuruvan, Priya V. Parandekar, Om Prakash, Thomas K. Tsotsis, Nisanth N. Nair
The
growing requisite for materials having high thermo-oxidative
stability makes the design and development of high performance materials
an active area of research. Fluorination of the polymer backbone is
a widely applied strategy to improve various properties of the polymer,
most importantly the thermo-oxidative stability. Many of these fluorinated
polymers are known to have thermo-oxidative stability up to 700 K.
However, for space and aerospace applications, it is important to
improve its thermo-oxidative stability beyond 700 K. Molecular-level
details of the thermo-oxidative degradation of such polymers can provide
vital information to improve the polymer. In this spirit, we have
applied quantum mechanical and microkinetic analysis to scrutinize
the mechanism and kinetics of the thermo-oxidative degradation of
a fluorinated polymer with phenylethenyl end-cap, HFPE. This study
gives an insight into the thermo-oxidative degradation of HFPE and
explains most of the experimental observations on the thermo-oxidative
degradation of this polymer. Thermolysis of C–CF3 bond in the dianhydride component (6FDA) of HFPE is found to be
the rate-determining step of the degradation. Reaction pathways that
are responsible for the experimentally observed weight loss of the
polymer is also scrutinized. On the basis of these results, we propose
a modification of HFPE polymer to improve its thermo-oxidative stability.