Poly(ether ester)s (PEEs) are an important class of thermoplastics that combine the good physical performance of both polyether and polyester blocks. However, their heterogeneous block structures complicate both the synthesis and the crystallization of PEEs. In this study, we synthesized a series of long-spaced PEEs with an alternative distribution of ether and ester segments from diethylene glycol (DEG) and n -methylene diacids ( n = 6–18) and investigated their polymorphic crystallization and phase transition. The melting temperature and crystallinity of PEEs enhance with increasing the CH 2 segment length of used diacid monomer. Interestingly, PEEs show temperature-dependent crystal polymorphism and multistage phase transition, depending on the CH 2 segment length and crystallization temperature ( T c ). Dual and triple crystal polymorphisms are found in the PEEs with medium CH 2 segments (growth of hexagonal form II and form I at low and high T c, respectively) and in those with long CH 2 segments (growth of orthorhombic form III, hexagonal form II, and form I at low, medium, and high T c, respectively). Phase transitions of form III to II and II to I are detected in PEEs upon heating, accompanied by the increase of structural stability. This study provides fundamental guidance for developing PEEs with tunable crystalline structures and properties.
Zheng et al. (Fri,) studied this question.