Open AccessTension-Induced Nematic Phase Separation in Bidisperse Homopolymer Melts
Author(s) -
Wenlin Zhang,
Ronald G. Larson
Publication year - 2018
Publication title -
acs central science
Language(s) - Uncategorized
Resource type - Journals
SCImago Journal Rank - 4.893
H-Index - 76
eISSN - 2374-7951
pISSN - 2374-7943
DOI - 10.1021/acscentsci.8b00651
Subject(s) - liquid crystal , surface tension , phase diagram , phase (matter) , molecular dynamics , materials science , coupling (piping) , polyethylene , extensional definition , thermodynamics , phase boundary , tension (geology) , flow (mathematics) , chemical physics , chemistry , mechanics , computational chemistry , organic chemistry , composite material , physics , compression (physics) , geology , paleontology , optoelectronics , tectonics
We use an analytical mean-field theory and all-atom molecular dynamics (MD) simulations to predict that external tension, together with the nematic coupling interactions, can drive phase separation of long chains from short ones in bidisperse homopolymer melts. The nematic coupling parameter α for polyethylene (PE) oligomers under applied tension is extracted from the MD simulations and used in the mean-field free energy to predict the phase boundary for bidisperse melts in which the longer chains are stretched by uniaxial tension. The predicted phase diagram is validated by direct MD simulations. We also show that extensional flow, and possibly even shear flow, may lead to nematic phase separation in molten PE oligomers, because the flow can impose a stronger tension on the longer chains than the short ones.
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