posted on 2020-03-10, 18:16authored byWei Li, Long Liu, Lirong Zheng, Yahui Lou, Zhe Ma, Yuesheng Li
The
intrinsic coupling effect between the multiscale microstructure
and macroscopic performance is a fundamental issue in polymer engineering
and polymer physics. Combing the tensile testing and in situ wide-angle
X-ray diffraction, the stretching-induced polymorphic transformation
from tetragonal form II into hexagonal form I in the butene-1/1,5-hexadiene
random copolymers was studied in this work. The mechanical response
and crystallite evolution of the designed copolymers with various
co-unit concentrations were combined to reveal the interplay between
macroscopic stretching and microscopic phase transition for the whole
deformation process. The results show that the elastic deformation
does not change the structure significantly and it is the yield that
triggers the II–I phase transition, which happens at a comparable
strain of around 0.06 for all polymers studied. It was indicated that
yield destroys the crystallite skeleton that bears the external stretching
in the elastic deformation region and the generation of new tie chains
enhances the stress transfer into lamellae, triggering the II–I
phase transition. The generation of more transformed form I improves
the stretching strength, and the increased stress is also required
to ensure the proceeding of phase transition. A direct correspondence
was established between the transition kinetics and true stress for
the course of the II–I phase transition. Furthermore, after
phase transition, the transformed form I increases the modulus of
the molecular network by 2 orders of magnitude with respect to that
of the original form II. This indicates that the crystallite acts
as the physical cross-links for the molecular network and the enhancement
of strain hardening is strongly dependent on the crystal modification.