Theory Of Strong Electrolytes Research Articles

One Hundred Years of Ghosh’s Strong Electrolyte Theory

Abnormal behaviour of strong electrolytes was a hot research topic around the turn of twentieth century. In 1918, J. C. Ghosh published a series of articles dealing with this abnormal behaviour and suggested a cube root law for data correlation. The publications were both praised and criticised. Debye and Huckel published in 1923 their well-known theory of strong electrolytes, the square root law, which completely overshadowed Ghosh’s theory. By the middle of twentieth century, however, Ghosh’s theory became prominent again, particularly for concentrated electrolyte solutions, in the light of pseudo-lattice theory of strong electrolytes. In this article, we discuss some features and historical developments of Ghosh’s theory to commemorate its centenary year.

New electrostatic model for highly charged surfaces

A new electrostatically self-consistent model for coulombic interactions near highly charged surfaces has been formulated. The model is based on electrostatic adsorption of counter-ions at the distance of closest approach. These adsorbed counter-ions are allowed to “bounce” up to a certain well-defined distance. Thus, there exists a region that is bounded by the bouncing distance and by the distance of closest approach, and from which the co-ions are expelled. This picture of the double layer arises from the self-consistent application of the Debye—Hückel theory of strong electrolytes and from the Manning idea of ion condensation. The model has so far given good prediction for four unrelated phenomena for which only “high” surface-charge density is a common denominator: the differential capacities at Hg/solution interfaces, the surface pressures of insoluble monolayers at oil/water interfaces, the activity coefficients of 2:2 electrolytes, and for the repulsions of two flat double layers.

New electrostatic model for highly charged surfaces

A new electrostatically self-consistent model for coulombic interactions near highly charged surfaces has been formulated. The model is based on electrostatic adsorption of counter-ions at the distance of closest approach. These adsorbed counter-ions are allowed to “bounce” up to a certain well-defined distance. Thus, there exists a region that is bounded by the bouncing distance and by the distance of closest approach, and from which the co-ions are expelled. This picture of the double layer arises from the self-consistent application of the Debye—Hückel theory of strong electrolytes and from the Manning idea of ion condensation. The model has so far given good prediction for four unrelated phenomena for which only “high” surface-charge density is a common denominator: the differential capacities at Hg/solution interfaces, the surface pressures of insoluble monolayers at oil/water interfaces, the activity coefficients of 2:2 electrolytes, and for the repulsions of two flat double layers.

Influence of the discreteness of nonlocalized charges on the interaction between the surfaces on their approach to one another

The interaction between charged interfaces at distances of the same order of magnitude or smaller than the mean distance between neighbouring charges depends on correlations of mutual positions of charges. A system has been considered in which electrostatic interaction is the single source of such correlations. Under conditions when the interactions between charges on the opposite interfaces are the determining factor, a correlation additive term to an ordinary averaged force (calculated for uniformly smeared out charges over the interfaces) is observed which is negative and inversely proportional to the gap thickness. Even if the interfaces are, on the whole, electrically neutral, then the taking into account the pairwise correlations leads to the appearance of noticeable attraction forces. This conclusion has been corroborated by the results of calculations based on a method similar to the Debye—Hückel theory of strong electrolytes.

An analytic solution of the non‐linear equation ∇2λ(r) = f(λ) and its application to the ion‐atmosphere theory of strong electrolytes

For a long time the formulation of a mathematically consistent statistical mechanical theory for a system of charged particles had remained a formidable unsolved problem. Recently, the problem had been satisfactorily solved, (see Bagchi [1] [2]) ,by utilizing the concept of ion‐atmosphere and generalized Poisson‐Boltzmann (PB) equation. Although the original Debye‐Hueckel (DH) theory of strong electrolytes [3] cannot be accepted as a consistent theory, neither mathematically nor physically, modified DH theory, in which the exclusion volumes of the ions enter directly into the distribution functions, had been proved to be mathematically consistent. It also yielded reliable physical results for both thermodynamic and transport properties of electrolytic solutions. Further, it has already been proved by the author from theoretical considerations (cf. Bagchi [4])as well as from a posteriori verification (see refs. [1] [2]) that the concept of ion‐atmosphere and the use of PB equation retain their validities generally. Now during the past 30 years, for convenice of calculations, various simplified versions of the original Dutta‐Bagchi distribution function (Dutta & Bagchi [5])had been used successfully in modified DH theory of solutions of strong electrolytes. The primary object of this extensive study, (carried out by the author during 1968‐73), was to decide a posteriori by using the exact analytic solution of the relevant PB equation about the most suitable, yet theoretically consistent, form of the distribution function. A critical analysis of these results eventually led to the formulation of a new approach to the statistical mechanics of classical systems, (see Bagchi [2]), In view of the uncertainties inherent in the nature of the system to be discussed below, it is believed that this voluminous work, (containing 35 tables and 120 graphs), in spite of its legitimate simplifying assumptions, would be of great assistance to those who are interested in studying the properties of ionic solutions from the standpoint of a physically and mathematically consistent theory.

On the foundations of a new approach to statistical mechanics of classical systems

It has been known for a long time that the fundamental approaches to equilibrium and nonequillbrium statistical mechanics available at present lead to physical and mathematical inconsistencies for dense systems. A new approach, whose foundation lies in the more powerful statistical method of counting complexions, had been formulated which not only overcomes all these difficulties but also yields satisfactory physical results for dense ′hard sphere′ systems as well as for systerns containing charged particles for which a mathematically consistent theory cannot even be formulated if we follow the available formalisms. The specific computational techniques rely on the following four recipes which also are justified theoretically.(i) The phase space (μ‐space) is separated into configuration space and momentum space.(ii) The configuration space is partitioned into cells of size b, the exclusion volume of Boltzmann.(iii) The partition function (pf) due to the kinetic energy is obtained directly from Planck′s “Zustandssumme” pertaining to the kinetic energies of the individual particles.(iv) Instead of calculating Gibbs′ configuration integral, one obtains the average potential of the system from a suitable nonlinear partial differential equatlon (pde) and finally the “excess” free energy of the system due to the potential field alone by utilizing Debye‐Hueckel′s concept of ion‐atmosphere and their technique for calculating the free energy.Even in the linear approximation of the ion‐atmosphere potential this method gives reliable results for both equilibrium and transport properties of fused alkali halides.In order to emphasize that this new approach has a secure theoretical foundation and has also considerable advantages over all other existing methods, this review offers a few brief critical remarks about the limitations and inadequacies of the concepts used in the conventional treatments of classical statistical mechanics. Further, in view of the fact that the literature on the subject of Debye‐Hueckel (DH) theory of strong electrolytes is replete with many assertions, already disproved in the past, a brief review of the controversial aspects of this theory is also presented. The next paper will show that this new approach as well as the modified DH theory yields physical results for actual dense systems much more satisfactorily than those which could be obtained by any other available method.

The Adjusted Screened Potential/Excluded Volume (ASPEV) Theory of Strong Electrolytes in Solution.

The Adjusted Screened Potential/Excluded Volume (ASPEV) Theory of Strong Electrolytes in Solution.

Polar Solvent Structure in the Debye-Hückel Theory of Strong Electrolytes

Abstract A general formula is derived for the potential energy of an ion in an ionic solution using all assumptions of the Debye-Hückel theory except the assumption of constant permittivity. For the solvent the spatial correlation of polarization fluctuations is taken into account. The potential energy of an ion in it's ionic atmosphere is calculated for different models of the spatial correlation of polarization fluctuations and the corresponding excess free energy and activity coefficient of an ion is evaluated. It is concluded that the Debye-Hückel theory using a constant value of e should only be valid for electrolyte concentrations lower than 10-7 mol · dm-3 . The paper intends to show the consequences of dropping the assumption of constant permittivity and so encourage further efforts towards a more exact treatment of the problem.

A Theory of Strong Electrolytes in Solution Based on a New Statistics. III. Equilibrium Phenomena : Activity Coefficients.

A Theory of Strong Electrolytes in Solution Based on a New Statistics. III. Equilibrium Phenomena : Activity Coefficients.

Dielectric Studies on Colloidal Solutions. I. High-frequency Conductivity of Aqueous Solutions of Paraffin-chain Salts

Abstract The high-frequency conductivity of solutions of sodium dodecyl sulphate, sodium oleate, and dodecyl amine hydrochloride was measured at frequencies of 15 and 30 Mc./sec. The high-frequency effect remarkably appeared at the concentration corresponding to the critical micelle concentration and the effect can be interpreted in terms of Debye-Falkenhagen’s theory of strong electrolytes. The appearance of maximum and gradual decrease in high-frequency effect may be explained by the shortening of the relaxation time or by the reduction of the electrostatic interaction due to the change of micelle structures with the increase of concentration.

The Statistical Mechanical Basis of the Debye–Hüekel Theory of Strong Electrolytes

ADVERTISEMENT RETURN TO ISSUEPREVArticleNEXTThe Statistical Mechanical Basis of the Debye–Hüekel Theory of Strong ElectrolytesJohn G. Kirkwood and Jacques C. PoirierCite this: J. Phys. Chem. 1954, 58, 8, 591–596Publication Date (Print):August 1, 1954Publication History Published online1 May 2002Published inissue 1 August 1954https://doi.org/10.1021/j150518a004RIGHTS & PERMISSIONSArticle Views808Altmetric-Citations137LEARN ABOUT THESE METRICSArticle Views are the COUNTER-compliant sum of full text article downloads since November 2008 (both PDF and HTML) across all institutions and individuals. These metrics are regularly updated to reflect usage leading up to the last few days.Citations are the number of other articles citing this article, calculated by Crossref and updated daily. Find more information about Crossref citation counts.The Altmetric Attention Score is a quantitative measure of the attention that a research article has received online. Clicking on the donut icon will load a page at altmetric.com with additional details about the score and the social media presence for the given article. Find more information on the Altmetric Attention Score and how the score is calculated. Share Add toView InAdd Full Text with ReferenceAdd Description ExportRISCitationCitation and abstractCitation and referencesMore Options Share onFacebookTwitterWechatLinked InReddit PDF (630 KB) Get e-Alerts

Attenuation of Sound Resulting from Ionic Relaxation

Slowness in the rearrangement of ion configuration under acoustic perturbation should cause sound absorption in ionic solutions. This mechanism investigated from the standpoint of the Debye-Ḧckel theory of strong electrolytes. The electrostatic part of the free energy of the solution is formulated in terms of temperature, volume, and an ion configuration function. The partial derivative of this expression with respect to volume gives the electrostatic component of pressure. A rate equation for change of ion concentration at a point enables us to find the variation in the ion configuration function with a small harmonic fluctuation in volume. Since the pressure is expressed in terms of the configuration function, this leads readily to the relaxational bulk modulus connected with rearrangement. The rate equation involves a parameter which in interionic theory has been identified as the relaxation time of the ionic atmospheres and can be evaluated from conductivity data. A calculation made for MgSO4 solutions sets the relaxation frequencies for 0.001 and 0.01 molal concentrations at 21 and 143 mc, respectively, and shows the maxima in the wavelength absorption coefficients to be 20 and 660× 10−9 respectively. The recently reported much higher excess absorptions for MgSO4 at lower frequencies are thus due to processes other than ionic relaxation.

On Bjerrum's Theory of Strong Electrolytes

On Bjerrum's Theory of Strong Electrolytes

A critical experimental investigation of the "force" method of determining the dielectric capacity of conducting liquids at low frequencies: Univalent electrolytes in aqueous solution

The theories of Debye, Onsager, and Falkenhagen, stressing the connexion between the dielectric constant and the other properties of solutions of electrolytes, have focussed a considerable amount of attention on the problem of the accurate determination of the dielectric properties of conducting solutions. The results, however, of work published by various investigators during the past few years show wide discrepancies and, in fact, it can hardly be said that even the sign of the effect of electrolytes upon the dielectric constant of water has yet been established with any degree of certainty. That the results have been so unsatisfactory is not altogether surprising in view of the inherent difficulties of the problem; the system itself is a complicated one, consisting of simple water dipoles, the polymers dihydrol and trihydrol, and the solute molecules or ions dispersed throughout the liquid; furthermore, the experimental technique is frequently complicated by the requirement that the dielectric constants shall be determined at frequencies low enough to permit of computation of the maximum possible polarization of the system, including the rotational polarization of all polar molecules which may be present. Methods involving the direct determination of the capacity of a condenser containing the liquid, whether by capacity-bridge or by resonance, are rendered difficult or inaccurate through the poor capacity sensitivity of such systems in presence of an appreciable ohmic conductivity between the condenser plates. This difficulty is minimized by the use of very high frequencies, and a considerable amount of work has been carried out under these conditions by Wien, Röver, Falkenhagen, and others in connexion with the theory of strong electrolytes. The need has arisen, however, for the values of the dielectric constants of solutions of large polar molecules such as long-chained amino acids, polypeptides, and soluble proteins. Such substances have considerably enhanced periods of relaxation, and proportionately low frequencies of alternating current must be employed to avoid loss of the orientation polarization of the system. In the case of pure egg-albumin solution, dispersion of hertzian waves occurs at all frequencies above about 10 5 sec. -1 . In view of this difficulty it seemed desirable that a thorough investigation should be made into the question as to whether precision results might be obtained from some general method which uses comparatively low frequencies of alternating current. The “force” method theoretically developed by Fürth, in 1924, seemed the most promising. Various modifications of this method have been used by many workers, unfortunately, however, with by no means concordant results, so far as conducting solutions are concerned. It consists broadly in the determination of the force exerted upon an ellipsoid, mounted to rotate about one of its minor axes, in a liquid dielectric across which an alternating field is applied in a direction at right angles to the axis of rotation of the ellipsoid. For such a system Fürth has shown that the torque on the ellipsoid may be expressed by εE 2 sin2θA, where ε represents the dielectric constant of the liquid, E the potential gradient, θ the angle between the major axis of the ellipsoid and the direction of the field, and A a constant involving the dimensions of the ellipsoid. This form of Fürth’s equation applies only so long as the resistance of the liquid dielectric is high relative to that of the ellipsoid itself.

The Virial Theorem and the Theory of Strong Electrolytes

Since the pioneer work of Prof. R. H. Fowler(1) on the statistical foundations of the Debye-Hückel theory of strong electrolytes (2), several attempts have been made to obtain as much information as possible on the question of the equation of state of electrolytes from merely thermodynamical and dimensional considerations.

The cataphoresis of suspended particles. Part I.—The equation of cataphoresis

§ 1. The theory of cataphoresis, and of the complementary phenomenon of electrosmosis, is based on the conception of an “ electrical double layer ” at the interface between the two phases whose relative motion is under consideration.* In the original theory, as propounded by Quincke and Helm­holtz, this electrical double layer was regarded as a kind of parallel plate condenser made up of two laminar distributions of electrification, of which one—the so-called “ inner sheet ”—was firmly attached to the rigid phase, while the other—the “ outer sheet ”—resided in the mobile phase ; the separation between the two was considered to be a distance of the order of molecular dimensions. The currently accepted view, initiated by Gouy, differs from that of Helmholtz chiefly in that the outer sheet of the double layer is con­sidered to be a diffuse distribution of electrification—an “ ionic atmosphere ” of the type investigated by Debye and his collaborators in connection with the theory of strong electrolytes. The net electric density in the ionic atmosphere varies continuously from a maximum in the immediate neighbourhood of the fixed inner sheet, to a negligibly small value in the bulk of the liquid, over a distance which is a function of the ionic concentration, and which lies as a rule between molecular dimensions and some thousand micromillimetres. In a deduction which appears to be completely consistent with this more modern view of the double layer, Smoluchowski deduced the expression U = DXζ/4π η (1) for the cataphoretic velocity U ; X is the applied field strength, ζ the potential difference across the double layer, D the dielectric constant and η the viscosity of the medium. The equation is identical with that developed by Helmholtz except for the inclusion of the dielectric constant, but was deduced on a much more general basis, and is claimed by Smoluchowski to be valid for rigid electrically insulating particles of any shape, subject only to the following four restrictions :— 1) That the usual hydrodynamical equations for the motion of a viscous fluid may be assumed to hold both in the bulk of the liquid and within the double layer; (2) That the motion is “stream line motion,” and slow enough for the “inertia terms” in the hydrodynamic equations to be neglected ; (3) That the applied field may be taken as simply superimposed on the field due to the electrical double layer ; and (4) That the thickness of the double layer ( i. e, the distance normal to the interface over which the potential differs appreciably from that in the bulk of the liquid) is small compared with the radius of curvature at any point of the surface.

The Theory of Strong Electrolytes: a General Discussion held by the Faraday Society, April 1927

The Theory of Strong Electrolytes: a General Discussion held by the Faraday Society, April 1927

The Theory of Strong Electrolytes

THE general discussion on “The Theory of Strong Electrolytes,” organised by the Faraday Society at Oxford on April 22 and 23, was rendered noteworthy by the foreign guests who were able to attend and to take part in the proceedings: Bjerrum, Brönsted, and Christianssen from Copenhagen, Faj ans from Munich, Hevesy from Freiburg, Hiickel (a former colleague of Debye) from G6ttingen, Onsager (a present colleague of Debye) from Zurich, Remy from Hamburg, and Ulich (a colleague of Walden) from Rostock, represented the European universities, whilst America was represented by Harned from the University of Pennsylvania and Scatchard from the Massachusetts Institute of Technology. The delegates enjoyed the hospitality of Exeter, Jesus, and Lincoln Colleges, and the informal discussions carried on there were not the least valuable features of the meeting.

On the Determination of the Apparent Diameters of the Ions in the Debye-Hückel Theory of Strong Electrolytes

On the Determination of the Apparent Diameters of the Ions in the Debye-Hückel Theory of Strong Electrolytes

The theory of strong electrolytes. A general discussion

The theory of strong electrolytes. A general discussion