Charged particles on surfaces: Coexistence of dilute phases and periodic structures at interfaces

Sharon M. Loverde; Francisco J. Solis; Monica Olvera De La Cruz

doi:10.1103/PhysRevLett.98.237802

Charged particles on surfaces: Coexistence of dilute phases and periodic structures at interfaces

Sharon M. Loverde^*, Francisco J. Solis, Monica Olvera De La Cruz

^*Corresponding author for this work

Materials Science and Engineering

Research output: Contribution to journal › Article › peer-review

39 Scopus citations

Abstract

We consider a mixture of two immiscible oppositely charged molecules strongly adsorbed to an interface, with a neutral nonselective molecular background. We determine the coexistence between a high density ionic periodic phase and a dilute isotropic ionic phase. We use a strong segregation approach for the periodic phase and determine the one-loop free energy for the dilute phase. Lamellar and hexagonal patterns are calculated for different charge stoichiometries of the mixture. Molecular dynamics simulations exhibit the predicted phase behavior. The periodic length scale of the solid phase is found to scale as ε/(lBψ3/2), where ψ is the effective charge density, lB is the Bjerrum length, and ε is the cohesive energy.

Original language	English (US)
Article number	237802
Journal	Physical review letters
Volume	98
Issue number	23
DOIs	https://doi.org/10.1103/PhysRevLett.98.237802
State	Published - Jun 6 2007

ASJC Scopus subject areas

Physics and Astronomy(all)

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10.1103/PhysRevLett.98.237802

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abstract = "We consider a mixture of two immiscible oppositely charged molecules strongly adsorbed to an interface, with a neutral nonselective molecular background. We determine the coexistence between a high density ionic periodic phase and a dilute isotropic ionic phase. We use a strong segregation approach for the periodic phase and determine the one-loop free energy for the dilute phase. Lamellar and hexagonal patterns are calculated for different charge stoichiometries of the mixture. Molecular dynamics simulations exhibit the predicted phase behavior. The periodic length scale of the solid phase is found to scale as ε/(lBψ3/2), where ψ is the effective charge density, lB is the Bjerrum length, and ε is the cohesive energy.",

author = "Loverde, {Sharon M.} and Solis, {Francisco J.} and {De La Cruz}, {Monica Olvera}",

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AU - Solis, Francisco J.

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Y1 - 2007/6/6

N2 - We consider a mixture of two immiscible oppositely charged molecules strongly adsorbed to an interface, with a neutral nonselective molecular background. We determine the coexistence between a high density ionic periodic phase and a dilute isotropic ionic phase. We use a strong segregation approach for the periodic phase and determine the one-loop free energy for the dilute phase. Lamellar and hexagonal patterns are calculated for different charge stoichiometries of the mixture. Molecular dynamics simulations exhibit the predicted phase behavior. The periodic length scale of the solid phase is found to scale as ε/(lBψ3/2), where ψ is the effective charge density, lB is the Bjerrum length, and ε is the cohesive energy.

AB - We consider a mixture of two immiscible oppositely charged molecules strongly adsorbed to an interface, with a neutral nonselective molecular background. We determine the coexistence between a high density ionic periodic phase and a dilute isotropic ionic phase. We use a strong segregation approach for the periodic phase and determine the one-loop free energy for the dilute phase. Lamellar and hexagonal patterns are calculated for different charge stoichiometries of the mixture. Molecular dynamics simulations exhibit the predicted phase behavior. The periodic length scale of the solid phase is found to scale as ε/(lBψ3/2), where ψ is the effective charge density, lB is the Bjerrum length, and ε is the cohesive energy.

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Charged particles on surfaces: Coexistence of dilute phases and periodic structures at interfaces

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