Structure Development in Semicrystalline Diblock Copolymers Crystallizing from the Ordered Melt

A. J. Ryan, I. W. Hamley, W. Bras, Frank S Bates

Research output: Contribution to journalArticlepeer-review

235 Scopus citations


Time-resolved simultaneous synchrotron small-angle and wide-angle X-ray scattering (SAXS and WAXS) and DSC experiments have been performed on poly(ethylene)-poly(ethylethylene) and polyethylene)—poly(ethylene-propylene) diblock copolymers quenched from melts with lamellar and hexagonal-packed cylinder structures. We find that the original microphase-separated morphologies are destroyed due to poly(ethylene) (PE) chain folding upon crystallization. Below the melting temperature, a sample with a volume fraction fPE = 0.49 forms a lamellar structure distinct from that in the melt. On quenching, a hexagonal fPE = 0.25 sample forms a lamellar structure similar to that of the fPE = 0.49 sample, while the hexagonal-packed cylinder structure of an fPE = 0.75 sample is also destroyed by crystallization but does not form well-ordered lamellae. The SAXS profiles from crystallized materials are shown to correspond to the sum of scattering from block copolymer lamellae, with up to four orders of reflection, plus a broad peak arising from semicrystalline PE. Analysis of scattering density correlation functions calculated using the SAXS data shows that the PE lamellar thickness is (45 ± 5) Å for all samples, similar to that observed for PE homopolymer. The WAXS data reveal that PE crystallizes in its usual orthorhombic form in all samples. The relative degree of crystallinity as a function of time after a quench, determined from the SAXS invariant, is fitted by Avrami equations for spherulitic crystallite growth. The Avrami exponent is found to be n = (3.0 ± 0.1) for all samples, consistent with a nucleation and growth process.

Original languageEnglish (US)
Pages (from-to)3860-3868
Number of pages9
Issue number11
StatePublished - May 1 1995


Dive into the research topics of 'Structure Development in Semicrystalline Diblock Copolymers Crystallizing from the Ordered Melt'. Together they form a unique fingerprint.

Cite this