Confinement free energy of flexible polyelectrolytes in spherical cavities

Rajeev Kumar, M. Muthukumar

Research output: Contribution to journalArticlepeer-review

22 Scopus citations

Abstract

A weakly charged flexible polyelectrolyte chain in a neutral spherical cavity is analyzed by using self-consistent field theory within an explicit solvent model. Assuming the radial symmetry for the system, it is found that the confinement of the chain leads to creation of a charge density wave along with the development of a potential difference across the center of cavity and the surface. We show that the solvent entropy plays an important role in the free energy of the confined system. For a given radius of the spherical cavity and fixed charge density along the backbone of the chain, solvent and small ion entropies dominate over all other contributions when chain lengths are small. However, with the increase in chain length, chain conformational entropy and polymer-solvent interaction energy also become important. Our calculations reveal that energy due to electrostatic interactions plays a minor role in the free energy. Furthermore, we show that the total free energy under spherical confinement is not extensive in the number of monomers. Results for the osmotic pressure and mean activity coefficient for monovalent salt are presented. We demonstrate that fluctuations at one-loop level lower the free energy and corrections to the osmotic pressure and mean activity coefficient of the salt are discussed. Finite size corrections are shown to widen the range of validity of the fluctuation analysis.

Original languageEnglish
Article number184902
JournalJournal of Chemical Physics
Volume128
Issue number18
DOIs
StatePublished - 2008
Externally publishedYes

Funding

We acknowledge financial support from NIH Grant 5R01HG002776-05, NSF Grant No. DMR 0605833, and the Material Research Science and Engineering Centre at the University of Massachusetts, Amherst.

FundersFunder number
Material Research Science and Engineering Centre at the University of Massachusetts, Amherst
National Science FoundationDMR 0605833
National Institutes of Health
National Human Genome Research InstituteR01HG002776

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