Balsara, N.
, Garetz, B.
, Newstein, M.
, Bauer, B.
and Prosa, T.
(1998),
Evolution of Microstructure in the Liquid and Crystal Directions in a Quenched Block Copolymer Melt and Its Implication on Phase Transition Mechanisms, Macromolecules
(Accessed April 19, 2024)
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Evolution of Microstructure in the Liquid and Crystal Directions in a Quenched Block Copolymer Melt and Its Implication on Phase Transition Mechanisms
Published
Author(s)
, B A. Garetz, M C. Newstein, ,
Abstract
Evolution of the disorder-to-order transition within a block copolymer is studied by the thermal quenching of samples from the melt to an ordered state. The ordered state consists of cylinders arranged on a hexagonal lattice and has liquid crystalline symmetry with liquid-like disorder along the cylinders axis and crystalline order in the hexagonal plane. We monitor the kinetics of microstructure formation in the liquid and crystalline directions by a combination of time-resolved depolarized light scattering and small angle x-ray scattering experiments. At small quench depths, microstructure formation along the liquid and crystalline directions is strongly correlated during all stages of the disorder-to-order transition. We demonstrate that this is expected when microstructure formation occurs by classical nucleation and growth; however, at large quench depths microstructure formation along the liquid and crystalline directions is not correlated. The growth of crystalline order occurs before the development of a coherent structure along the liquid direction. We argue that this may be a signature of spinodal decomposition in liquid crystals.Citation
Macromolecules
Volume
31
Issue
No. 22
Pub Type
Journals
Keywords
block copolymer, depolarized light scattering, order-disorder phase transition, small angle x-ray scattering, spinodal decomposition
Citation
Created November 1, 1998, Updated February 19, 2017