Ions at hydrophobic interfaces

Levin, Yan; Santos, Alexandre Pereira dos

doi:10.1088/0953-8984/26/20/203101

Cited by 50 publications

(74 citation statements)

References 110 publications

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“…The empirical polarizable energy as used in some molecular dynamics simulation 53, 70 was not considered. The experimentally measured values for Δ ψ for a two-state model as listed in Table 2, first column, are larger than the values from the simulations for surfaces whose solvent density or solvent dielectric constant is assumed to vary continuously across the surfaces 70–72 . For anions consisting of a single atom such as Cl − , Br − , and I − , the calculated Δ ψ matches the experimental Δ ψ value better when the image charge potential 44 at the surface and its hydrophobic hydration energy of the hydrated ion radius are considered.…”

Section: Excess Charge Density At the Interface: Separating Electrmentioning

confidence: 77%

Ion specific effects: decoupling ion–ion and ion–water interactions

Song

Kang

Kim

et al. 2015

Phys. Chem. Chem. Phys.

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Ion-specific effects in aqueous solution, known as the Hofmeister effect is prevalent in diverse systems ranging from pure ionic to complex protein solutions. The objective of this paper is to explicitly demonstrate how complex ion-ion and ion-water interactions manifest themselves in the Hofmeister effects, based on a series of recent experimental observation. These effects are not considered in the classical description of ion effects, such as the Deryaguin-Landau-Verwey-Overbeek (DLVO) theory that, likely for that reason, fail to describe the origin of the phenomenological Hofmeister effect. However, given that models considering the basic forces of electrostatic and van der Waals interactions can offer rationalization for the core experimental observations, a universal interaction model stands a chance to be developed. In this perspective, we separately derive the contribution from ion-ion electrostatic interaction and ion-water interaction from second harmonic generation (SHG) data at the air-ion solution interface, which yields an estimate of ion-water interactions in solution. Hofmeister ion effects observed on biological solutes in solution should be similarly influenced by contributions from ion-ion and ion-water interactions, where the same ion-water interaction parameters derived from SHG data at the air-ion solution interface could be applicable. A key experimental data set available from solution systems to probe ion-water interaction is the modulation of water diffusion dynamics near ions in bulk ion solution, as well as near biological liposome surfaces. It is obtained from Overhauser dynamic nuclear polarization (ODNP), a nuclear magnetic resonance (NMR) relaxometry technique. The surface water diffusivity is influenced by the contribution from ion-water interactions, both from localized surface charges and adsorbed ions, although the relative contribution of the former is larger on liposome surfaces. In this perspective, ion-water interaction energy values derived from experimental data for various ions are compared with theoretical values in the literature. Ultimately, quantifying ion-induced changes in surface energy for the purpose of developing valid theoretical models for ion-water interaction, will be critical to rationalizing the Hofmeister effect.

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Section: Excess Charge Density At the Interface: Separating Electrmentioning

confidence: 77%

Ion specific effects: decoupling ion–ion and ion–water interactions

Song

Kang

Kim

et al. 2015

Phys. Chem. Chem. Phys.

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“…[10][11][12][13][14][15][16][17][18] Ionic specificity was first suggested to be due to dispersion interactions between ions and water; 10 this, however, was later shown not to be the case. [19][20][21][22][23][24][25][26] Recently we developed a theory which allows us to calculate the excess surface tensions of electrolyte-air interface in very good agreement with the experimental data. 24,[26][27][28] In theory, the chaotropic anions are allowed to adsorb to the interface, while kosmotropic ions remain hydrated in the aqueous medium.…”

Section: Introductionmentioning

confidence: 80%

Effective charges and zeta potentials of oil in water microemulsions in the presence of Hofmeister salts

Santos

Levin

2018

The Journal of Chemical Physics

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We present a theory which allows us to calculate the effective charge and zeta potential of oil droplets in microemulsions containing Hofmeister salts. A modified Poisson-Boltzmann equation is used to account for the surface and ion polarizations and hydrophobic and dispersion interactions. The ions are classified as kosmotropes and chaotropes according to their Jones-Dole viscosity B coefficient. Kosmotropes stay hydrated and do not enter into the oil phase, while chaotropes can adsorb to the oil-water interface. The effective interaction potentials between ions and oil-water interface are parametrized so as to accurately account for the excess interfacial tension.

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“…168,169 In this model, proton adsorption is the result of a square well potential positioned at ∼1 HB length from the interface. Given this ansatz, a square well potential chosen so as to give a proton adsorption free energy of −7.5 kJ/mol results in calculated surface tensions that reproduce the experimental values for solutions of most hydrohalous acids.…”

Section: Theoretical Descriptionmentioning

confidence: 99%

Protons and Hydroxide Ions in Aqueous Systems

et al. 2016

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Understanding the structure and dynamics of water's constituent ions, proton and hydroxide, has been a subject of numerous experimental and theoretical studies over the last century. Besides their obvious importance in acid-base chemistry, these ions play an important role in numerous applications ranging from enzyme catalysis to environmental chemistry. Despite a long history of research, many fundamental issues regarding their properties continue to be an active area of research. Here, we provide a review of the experimental and theoretical advances made in the last several decades in understanding the structure, dynamics, and transport of the proton and hydroxide ions in different aqueous environments, ranging from water clusters to the bulk liquid and its interfaces with hydrophobic surfaces. The propensity of these ions to accumulate at hydrophobic surfaces has been a subject of intense debate, and we highlight the open issues and challenges in this area. Biological applications reviewed include proton transport along the hydration layer of various membranes and through channel proteins, problems that are at the core of cellular bioenergetics.

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Ions at hydrophobic interfaces

Cited by 50 publications

References 110 publications

Ion specific effects: decoupling ion–ion and ion–water interactions

Ion specific effects: decoupling ion–ion and ion–water interactions

Effective charges and zeta potentials of oil in water microemulsions in the presence of Hofmeister salts

Protons and Hydroxide Ions in Aqueous Systems

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