Activity coefficient



An activity coefficient [1] is a factor used in enthalpy of mixing is zero) and, as a result, properties of the mixtures can be be expressed directly in terms of simple fugacity coefficient.

These examples can be understood by considering the chemical potential of each substance in the mixture. The chemical potential, μB, of a substance B in an ideal mixture is given by

\mu_B = \mu_{B}^{\ominus} + RT \ln x_B \,

where \mu_{B}^{\ominus} is the chemical potential in the mole fraction of the substance in the mixture.

This is generalised to include non-ideal behaviour by writing

\mu_B = \mu_{B}^{\ominus} + RT \ln a_B \,

when aB is the activity of the substance in the mixture with

aB = xBγB

where γB is the activity coefficient. As mole fraction or concentration tends of B tends to zero, the behaviour of the mixture more closely approximates to ideal, and so the activity coefficients (of both solute and solvent) tend to unity in very dilute solutions. Note that in general activity coefficients are dimensionless.

Modifying mole fractions or concentrations by activity coefficients gives the effective activities of the components, and hence allows expressions such as equilibrium constants constants to be applied to both ideal and non-ideal mixtures.

Knowledge of activity coefficients is particularly important in the context of electrolyte solutions is often far from ideal, due the effects of the ionic atmosphere.

Measurement and prediction of activity coefficients

Activity coefficients may be measured experimentally or calculated theoretically, using the UNIFAC may be employed, provided fitted model parameters are avaiable

For uncharged species, the activity coefficient γ0 mostly follows a "salting-out" model[5]:

log100) = bI

This simple model predicts activities of many species (dissolved undissociated gases such as CO2, H2S, NH3, undissociated acids and bases) to high ionic strengths (up to 5 mol/kg). The value of the constant b for CO2 is 0.11 at 10 °C and 0.20 at 330 °C[6][7].

For water, the activity coefficient γw can be calculated using[citation needed]:

\ln(\gamma_{w}) = \frac{-\nu m \phi }{55.51}

where ν is the number of ions produced from the dissociation of one molecule of the dissolved salt, m is the molal concentration of the salt dissolved in water, Φ is the osmotic coefficient of water, and the constant 55.51 represents the molal concentration of water.

References

  1. ^ Gold Book definition
  2. ^ C.W. Davies, Ion Association,Butterworths, 1962
  3. ^ I. Grenthe and H. Wanner, Guidelines for the extrapolation to zero ionic strength, http://www.nea.fr/html/dbtdb/guidelines/tdb2.pdf
  4. ^ SIT theory
  5. ^ J.N. Butler, "Ionic Equilibrium", John Wiley and Sons, Inc., 1998.
  6. ^ A.J. Elis and R.M. Golding, Am. J. Sci, 162, p 47-60, 1963.
  7. ^ S.D.Malinin, Geokhimiya, 3, p. 235-245, 1959.
 
This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article "Activity_coefficient". A list of authors is available in Wikipedia.