Direct Measurement of Interfacial Curvature Distributions in a Bicontinuous Block Copolymer Morphology
- 17 January 2000
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 84 (3) , 518-521
- https://doi.org/10.1103/physrevlett.84.518
Abstract
Self-consistent field theory predicts that the complex phase behavior of block copolymers does not originate solely from the interface seeking constant mean curvature as once thought, but instead reflects competing minimization of interfacial tension and packing frustration. To test this prediction, we directly measure interfacial curvature distributions from a 3D image reconstruction of the bicontinuous gyroid morphology. Results obtained here reveal that the gyroid interface is not constant mean curvature and confirm the importance of packing frustration in the stabilization of such complex nanostructures.Keywords
This publication has 23 references indexed in Scilit:
- Curvature distributions of spinodal interface in a condensed matter systemPhysical Review E, 1999
- Bicontinuous Morphologies in Homologous Multiblock Copolymers and Their Homopolymer BlendsMacromolecules, 1998
- Measurements of Interfacial Curvatures of Bicontinuous Structure from Three-Dimensional Digital Images. 1. A Parallel Surface MethodLangmuir, 1998
- Microstructural Analysis of a Cubic Bicontinuous Morphology in a Neat SIS Triblock CopolymerMacromolecules, 1997
- Complex Phase Behavior of a Disordered “Random” Diblock Copolymer in the Presence of a Parent HomopolymerLangmuir, 1997
- Curvature Determination of Spinodal Interface in a Condensed Matter SystemPhysical Review Letters, 1997
- Block copolymer microstructures in the intermediate-segregation regimeThe Journal of Chemical Physics, 1997
- Complex Phase Behavior of Polyisoprene-Polystyrene Diblock Copolymers Near the Order-Disorder TransitionMacromolecules, 1994
- Ordered bicontinuous double-diamond structure of star block copolymers: a new equilibrium microdomain morphologyMacromolecules, 1986
- Constant variance enhancement: a digital processing techniqueApplied Optics, 1977