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Literature DB >> 17026401

Attraction between like-charged walls: Short-ranged simulations using local molecular field theory.

Jocelyn M Rodgers¹, Charanbir Kaur, Yng-Gwei Chen, John D Weeks.

Abstract

Effective attraction between like-charged walls mediated by counterions is studied using local molecular field (LMF) theory. Monte Carlo simulations of the "mimic system" given by LMF theory, with short-ranged "Coulomb core" interactions in an effective single particle potential incorporating a mean-field average of the long-ranged Coulomb interactions, provide a direct test of the theory, and are in excellent agreement with more complex simulations of the full Coulomb system by Moreira and Netz [Eur. Phys. J. E 8, 33 (2002)]. A simple, generally applicable criterion to determine the consistency parameter sigma(min) needed for accurate use of the LMF theory is presented.

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Substances：
DNA

Year: 2006 PMID： 17026401 DOI： 10.1103/PhysRevLett.97.097801

Source DB: PubMed Journal: Phys Rev Lett ISSN： 0031-9007 Impact factor: 9.161

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Cited

7 in total

1. Interplay of local hydrogen-bonding and long-ranged dipolar forces in simulations of confined water.

Authors: Jocelyn M Rodgers; John D Weeks
Journal: Proc Natl Acad Sci U S A Date: 2008-12-08 Impact factor: 11.205

2. One-dimensional counterion gas between charged surfaces: exact results compared with weak- and strong-coupling analyses.

Authors: David S Dean; Ron R Horgan; Ali Naji; Rudolf Podgornik
Journal: J Chem Phys Date: 2009-03-07 Impact factor: 3.488

Attraction between like-charged walls: Short-ranged simulations using local molecular field theory.

1. Interplay of local hydrogen-bonding and long-ranged dipolar forces in simulations of confined water.

2. One-dimensional counterion gas between charged surfaces: exact results compared with weak- and strong-coupling analyses.

Review 3. Dewetting and hydrophobic interaction in physical and biological systems.

4. Lamellar phase coexistence induced by electrostatic interactions.

5. Counter-ions at charged walls: two-dimensional systems.

6. Multivalent counterions induced attraction between DNA polyelectrolytes.

Review 7. DNA under Force: Mechanics, Electrostatics, and Hydration.