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The molar conductivity of an electrolyte solution is defined as its conductivity divided by its molar concentration. : \Lambda_\text = \frac, where: : ''κ'' is the measured conductivity (formerly known as specific conductance), : ''c'' is the
molar concentration Molar concentration (also called molarity, amount concentration or substance concentration) is a measure of the concentration of a chemical species, in particular of a solute in a solution, in terms of amount of substance per unit volume of sol ...
of the electrolyte. The
SI unit The International System of Units, known by the international abbreviation SI in all languages and sometimes Pleonasm#Acronyms and initialisms, pleonastically as the SI system, is the modern form of the metric system and the world's most wid ...
of molar conductivity is siemens metres squared per mole (S m2 mol−1). However, values are often quoted in S cm2 mol−1. In these last units, the value of Λm may be understood as the conductance of a volume of solution between parallel plate electrodes one centimeter apart and of sufficient area so that the solution contains exactly one mole of electrolyte.


Variation of molar conductivity with dilution

There are two types of electrolytes: strong and weak. Strong electrolytes usually undergo complete ionization, and therefore they have higher conductivity than weak electrolytes, which undergo only partial ionization. For strong electrolytes, such as
salts In chemistry, a salt is a chemical compound consisting of an ionic assembly of positively charged cations and negatively charged anions, which results in a compound with no net electric charge. A common example is table salt, with positively ...
,
strong acid Acid strength is the tendency of an acid, symbolised by the chemical formula HA, to dissociate into a proton, H+, and an anion, A-. The dissociation of a strong acid in solution is effectively complete, except in its most concentrated solutio ...
s and strong bases, the molar conductivity depends only ''weakly'' on concentration. On dilution there is a regular increase in the molar conductivity of strong electrolyte, due to the decrease in solute–solute interaction. Based on experimental data Friedrich Kohlrausch (around the year 1900) proposed the non-linear law for strong electrolytes: : \Lambda_\text =\Lambda_\text^\circ - K\sqrt = \alpha f_\lambda \Lambda_\text^\circ, where : Λ is the molar conductivity at infinite dilution (or ''limiting molar conductivity''), which can be determined by extrapolation of Λm as a function of , : ''K'' is the Kohlrausch coefficient, which depends mainly on the stoichiometry of the specific salt in solution, : ''α'' is the dissociation degree even for strong concentrated electrolytes, : ''fλ'' is the lambda factor for concentrated solutions. This law is valid for low electrolyte concentrations only; it fits into the Debye–Hückel–Onsager equation. For weak electrolytes (i.e. incompletely dissociated electrolytes), however, the molar conductivity ''strongly'' depends on concentration: The more dilute a solution, the greater its ''molar'' conductivity, due to increased ionic dissociation. For example, acetic acid has a higher molar conductivity in dilute aqueous acetic acid than in concentrated acetic acid.


Kohlrausch's law of independent migration of ions

Friedrich Kohlrausch in 1875–1879 established that to a high accuracy in dilute solutions, molar conductivity can be decomposed into contributions of the individual ions. This is known as Kohlrausch's law of independent ionic migration. For any electrolyte A''x''B''y'', the limiting molar conductivity is expressed as ''x'' times the limiting molar conductivity of A''y''+ and ''y'' times the limiting molar conductivity of B''x''−. : \Lambda_\text^\circ = \Sigma_i \nu_i \lambda_i, where: : ''λi'' is the limiting molar ionic conductivity of ion ''i'', : ''νi'' is the number of ions ''i'' in the formula unit of the electrolyte (e.g. 2 and 1 for Na+ and in Na2SO4). Kohlrausch's evidence for this law was that the limiting molar conductivities of two electrolytes with two different cations and a common anion differ by an amount which is independent of the nature of the anion. For example, = for X = Cl, I and  . This difference is ascribed to a difference in ionic conductivities between K+ and Na+. Similar regularities are found for two electrolytes with a common anion and two cations.


Molar ionic conductivity

The molar ionic conductivity of each ionic species is proportional to its
electrical mobility Electrical mobility is the ability of charged particles (such as electrons or protons) to move through a medium in response to an electric field that is pulling them. The separation of ions according to their mobility in gas phase is called ion ...
(''μ''), or
drift velocity In physics, a drift velocity is the average velocity attained by charged particles, such as electrons, in a material due to an electric field. In general, an electron in a conductor will propagate randomly at the Fermi velocity, resulting in an ...
per unit electric field, according to the equation :\lambda = z \mu F where ''z'' is the ionic charge, and ''F'' is the
Faraday constant In physical chemistry, the Faraday constant, denoted by the symbol and sometimes stylized as ℱ, is the electric charge per mole of elementary charges. It is named after the English scientist Michael Faraday. Since the 2019 redefinition of S ...
. The limiting molar conductivity of a weak electrolyte cannot be determined reliably by extrapolation. Instead it can be expressed as a sum of ionic contributions, which can be evaluated from the limiting molar conductivities of strong electrolytes containing the same ions. For aqueous
acetic acid Acetic acid , systematically named ethanoic acid , is an acidic, colourless liquid and organic compound with the chemical formula (also written as , , or ). Vinegar is at least 4% acetic acid by volume, making acetic acid the main componen ...
as an example, : \begin \Lambda_\text^\circ(\ce) &= \lambda(\ce) + \lambda(\ce) \\ &= \Lambda_\text^\circ(\ce) + \Lambda_\text^\circ(\ce) - \Lambda_\text^\circ(\ce). \end Values for each ion may be determined using measured
ion transport number In chemistry, ion transport number, also called the transference number, is the fraction of the total electric current carried in an electrolyte by a given ionic species : :t_i = \frac Differences in transport number arise from differences in ...
s. For the cation: : \lambda^+ = t_+ \cdot \frac and for the anion: : \lambda^- = t_- \cdot \frac. Most monovalent ions in water have limiting molar ionic conductivities in the range of . For example: Laidler K. J. and Meiser J. H., ''Physical Chemistry'' (Benjamin/Cummings 1982) p. 281–283. . The order of the values for alkali metals is surprising, since it shows that the smallest cation Li+ moves more slowly in a given electric field than Na+, which in turn moves more slowly than K+. This occurs because of the effect of
solvation Solvation (or dissolution) describes the interaction of a solvent with dissolved molecules. Both ionized and uncharged molecules interact strongly with a solvent, and the strength and nature of this interaction influence many properties of the ...
of water molecules: the smaller Li+ binds most strongly to about four water molecules so that the moving cation species is effectively . The solvation is weaker for Na+ and still weaker for K+. The increase in halogen ion mobility from F to Cl to Br is also due to decreasing solvation. Exceptionally high values are found for H+ () and OH (), which are explained by the Grotthuss proton-hopping mechanism for the movement of these ions. The H+ also has a larger conductivity than other ions in
alcohol Alcohol most commonly refers to: * Alcohol (chemistry), an organic compound in which a hydroxyl group is bound to a carbon atom * Alcohol (drug), an intoxicant found in alcoholic drinks Alcohol may also refer to: Chemicals * Ethanol, one of sev ...
s, which have a
hydroxyl In chemistry, a hydroxy or hydroxyl group is a functional group with the chemical formula and composed of one oxygen atom covalently bonded to one hydrogen atom. In organic chemistry, alcohols and carboxylic acids contain one or more hydrox ...
group, but behaves more normally in other solvents, including liquid
ammonia Ammonia is an inorganic compound of nitrogen and hydrogen with the formula . A stable binary hydride, and the simplest pnictogen hydride, ammonia is a colourless gas with a distinct pungent smell. Biologically, it is a common nitrogeno ...
and
nitrobenzene Nitrobenzene is an organic compound with the chemical formula C6H5 NO2. It is a water-insoluble pale yellow oil with an almond-like odor. It freezes to give greenish-yellow crystals. It is produced on a large scale from benzene as a precursor ...
. For multivalent ions, it is usual to consider the conductivity divided by the equivalent ion concentration in terms of equivalents per litre, where 1 equivalent is the quantity of ions that have the same amount of electric charge as 1 mol of a monovalent ion:  mol Ca2+,  mol ,  mol Al3+,  mol , etc. This quotient can be called the ''equivalent conductivity'', although
IUPAC The International Union of Pure and Applied Chemistry (IUPAC ) is an international federation of National Adhering Organizations working for the advancement of the chemical sciences, especially by developing nomenclature and terminology. It is ...
has recommended that use of this term be discontinued and the term molar conductivity be used for the values of conductivity divided by equivalent concentration.Yung Chi Wu and Paula A. Berezansky
Low Electrolytic Conductivity Standards
J. Res. Natl. Inst. Stand. Technol. 100, 521 (1995).
If this convention is used, then the values are in the same range as monovalent ions, e.g. for  Ca2+ and for  . From the ionic molar conductivities of cations and anions, effective ionic radii can be calculated using the concept of Stokes radius. The values obtained for an ionic radius in solution calculated this way can be quite different from the
ionic radius Ionic radius, ''r''ion, is the radius of a monatomic ion in an ionic crystal structure. Although neither atoms nor ions have sharp boundaries, they are treated as if they were hard spheres with radii such that the sum of ionic radii of the catio ...
for the same ion in crystals, due to the effect of hydration in solution.


Applications

Ostwald's law of dilution, which gives the dissociation constant of a weak electrolyte as a function of concentration, can be written in terms of molar conductivity. Thus, the p''K''a values of acids can be calculated by measuring the molar conductivity and extrapolating to zero concentration. Namely, p''K''a = p() at the zero-concentration limit, where ''K'' is the dissociation constant from Ostwald's law.


References

{{reflist Electrochemical concepts Physical chemistry