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Conformational Polymorphism of Amphiphilic Polymers in a Poor Solvent

To simulate amphiphilic polymers, we introduce an extended hydrophobic/hydrophilic (HP) model which, in contrast to the standard “beads-on-a-string” HP model, incorporates the dualistic nature of monomer units, each consisting of hydrophobic (H) and hydrophilic (P) interaction sites. For this coarse...

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Published in:	Macromolecules 2003-12, Vol.36 (26), p.10103-10111
Main Authors:	Vasilevskaya, Valentina V, Khalatur, Pavel G, Khokhlov, Alexei R
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Language:	English
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description	To simulate amphiphilic polymers, we introduce an extended hydrophobic/hydrophilic (HP) model which, in contrast to the standard “beads-on-a-string” HP model, incorporates the dualistic nature of monomer units, each consisting of hydrophobic (H) and hydrophilic (P) interaction sites. For this coarse-grained model, the hydrophobically driven conformational transitions are studied using extensive molecular dynamics simulations. We find that, depending on the interaction between H and P sites, a variety of thermodynamically stable anisometric chain morphologies are possible in a solvent selectively poor for H sites, including disklike structures, stretched strings of intramolecular micelles, and cylindrical-shaped conformations. These microstructures are formed due to intramolecular segregation of chemically different H and P groups. Under certain conditions, the chain size R g as a function of solvent quality can behave in a nonmonotonic manner, showing an increase when the solvent becomes poorer for hydrophobic sites. For the range of the chain lengths N simulated (N ≤ 1024), the formation of highly anisotropic conformations can lead to the R g ∝ N 0.9 scaling.
doi_str_mv	10.1021/ma0350563
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title	Conformational Polymorphism of Amphiphilic Polymers in a Poor Solvent
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