Understanding the Electric Double Layer at the Electrode‐Electrolyte Interface: Part I – No Ion Specific Adsorption

Mazur, Daria A.; Brandyshev, Petr E.; Doronin, Sergey V.; Budkov, Yury A.

doi:10.1002/cphc.202400650

ChemPhysChem

2024

DOI: 10.1002/cphc.202400650

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Understanding the Electric Double Layer at the Electrode‐Electrolyte Interface: Part I – No Ion Specific Adsorption

Daria A. Mazur,

Petr E. Brandyshev,

Sergey V. Doronin

et al.

Abstract: We present a comprehensive mean‐field model that takes into account the key components of modern electrical double layer theory at the interface between an electrode and an electrolyte solution. The model considers short‐range specific interactions between different species, including electrode‐ion repulsion, the hydration of ions, dielectric saturation of solvent (water), and excluded volume (steric) interactions between species. By solving a modified Poisson‐Boltzmann equation and using the appropriate resul… Show more

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Modified Debye–Hückel–Onsager theory for electrical conductivity in aqueous electrolyte solutions: Account of ionic charge nonlocality

Kalikin,

Budkov

2024

The Journal of Chemical Physics

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This paper presents a mean field theory of electrolyte solutions, extending the classical Debye–Hückel–Onsager theory to provide a detailed description of the electrical conductivity in strong electrolyte solutions. The theory systematically incorporates the effects of ion specificity, such as steric interactions, hydration of ions, and their spatial charge distributions, into the mean-field framework. This allows for the calculation of ion mobility and electrical conductivity, while accounting for relaxation and hydrodynamic phenomena. At low concentrations, the model reproduces the well-known Kohlrausch’s limiting law. Using the exponential (Slater-type) charge distribution function for solvated ions, we demonstrate that experimental data on the electrical conductivity of aqueous 1:1, 2:1, and 3:1 electrolyte solutions can be approximated over a broad concentration range by adjusting a single free parameter representing the spatial scale of the nonlocal ion charge distribution. Using the fitted value of this parameter at 298.15 K, we obtain good agreement with the available experimental data when calculating electrical conductivity across different temperatures. We also analyze the effects of temperature and electrolyte concentration on the relaxation and electrophoretic contributions to total electrical conductivity, explaining the underlying physical mechanisms responsible for the observed behavior.

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Modified Debye–Hückel–Onsager theory for electrical conductivity in aqueous electrolyte solutions: Account of ionic charge nonlocality

Kalikin,

Budkov

2024

The Journal of Chemical Physics

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show abstract

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Understanding the Electric Double Layer at the Electrode‐Electrolyte Interface: Part I – No Ion Specific Adsorption

Cited by 1 publication

References 86 publications

Modified Debye–Hückel–Onsager theory for electrical conductivity in aqueous electrolyte solutions: Account of ionic charge nonlocality

Modified Debye–Hückel–Onsager theory for electrical conductivity in aqueous electrolyte solutions: Account of ionic charge nonlocality

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