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An '''osmotic coefficient''' ''φ'' is a quantity which characterises the deviation of a [[solvent]] from [[ideal solution|ideal behaviour]], referenced to [[Raoult's law]]. It can be also applied to solutes. Its definition depends on the ways of expressing [[chemical composition]] of mixtures.
{{Short description|Quantity characterizing the deviation of a solvent from ideal behavior}}
An '''osmotic coefficient''' <math>\phi</math> is a quantity which characterises the deviation of a [[solvent]] from [[ideal solution|ideal behaviour]], referenced to [[Raoult's law]]. It can be also applied to solutes. Its definition depends on the ways of expressing [[chemical composition]] of mixtures.


The osmotic coefficient based on [[molality]] ''b'' is defined by:
The osmotic coefficient based on [[molality]] ''m'' is defined by:
: <math>\varphi=\frac{\mu_A^*-\mu_A}{RTM_A\sum_i b_i}\,</math>
<math display="block">\phi = \frac{\mu_A^* - \mu_A}{RTM_A \sum_i m_i}</math>


and on a [[mole fraction]] basis by:
and on a [[mole fraction]] basis by:


:<math>\varphi=-\frac{\mu_A^*-\mu_A}{RT \ln x_A}\,</math>
<math display="block">\phi = -\frac{\mu_A^* - \mu_A}{RT \ln x_A}</math>


where <math>\mu_A^*</math> is the [[chemical potential]] of the pure solvent and <math>\mu_A</math> is the [[chemical potential]] of the solvent in a solution, ''M''<sub>A</sub> is its [[molar mass]], ''x''<sub>A</sub> its [[mole fraction]], ''R'' the [[gas constant]] and ''T'' the [[temperature]] in [[kelvin]]s.<ref>{{GoldBookRef|title=osmotic coefficient| file = O04342}}</ref> The latter osmotic
where <math>\mu_A^*</math> is the [[chemical potential]] of the pure solvent and <math>\mu_A</math> is the [[chemical potential]] of the solvent in a solution, ''M''<sub>A</sub> is its [[molar mass]], ''x''<sub>A</sub> its [[mole fraction]], ''R'' the [[gas constant]] and ''T'' the [[temperature]] in [[Kelvin]].<ref>{{GoldBookRef|title=osmotic coefficient| file = O04342}}</ref> The latter osmotic
coefficient is sometimes called the '''rational osmotic coefficient'''. The values for the two definitions are different, but since
coefficient is sometimes called the '''rational osmotic coefficient'''. The values for the two definitions are different, but since


:<math>\ln x_A = - \ln(1 + M_A \sum_i b_i) \approx - M_A \sum_i b_i,</math>
<math display="block">\ln x_A = - \ln \left(1 + M_A \sum_i m_i \right) \approx - M_A \sum_i m_i,</math>


the two definitions are similar, and in fact both approach 1 as the concentration goes to zero.
the two definitions are similar, and in fact both approach 1 as the concentration goes to zero.

== Applications ==
For liquid solutions, the osmotic coefficient is often used to calculate the salt [[activity coefficient]] from the solvent activity, or vice versa. For example, [[freezing point depression]] measurements, or measurements of deviations from ideality for other [[colligative properties]], allows calculation of the salt activity coefficient through the osmotic coefficient.

==Relation to other quantities==
==Relation to other quantities==
In a single solute solution, the (molality based) osmotic coefficient and the solute [[activity coefficient]] are related to the [[excess chemical potential|excess Gibbs free energy]] <math>G^E</math> by the relations:
In a single solute solution, the (molality based) osmotic coefficient and the solute activity coefficient <math>\gamma </math> are related to the [[excess chemical potential|excess Gibbs free energy]] <math>G^E</math> by the relations:


:<math>RTb(1-\varphi) = G^E - b \frac{dG^E}{db}</math>
:<math>RTm(1-\phi) = G^E - m \frac{dG^E}{dm}</math>
:<math>RT\ln\gamma = \frac{dG^E}{db}</math>
:<math>RT\ln\gamma = \frac{dG^E}{dm}</math>


and there is thus a differential relationship between them (temperature and pressure held constant):
and there is thus a differential relationship between them (temperature and pressure held constant):
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:<math>d((\varphi -1)b + b) = b d \ln\gamma + b d\ln b</math>
:<math>d((\varphi -1)b + b) = b d \ln\gamma + b d\ln b</math>
-->
-->
:<math>d((\varphi -1)b) = b d (\ln\gamma)</math>
:<math>d((\phi -1)m) = m d (\ln\gamma)</math>

=== Liquid electrolyte solutions ===
For a single salt solute with molal activity (<math>\gamma_\pm m</math>), the osmotic coefficient can be written as <math>\phi=\frac{-\ln(a_A)}{\nu m M_A}</math>where <math>\nu</math> is the stochiometric number of salt and <math>a_A</math> the activity of the solvent. <math>\phi</math> can be calculated from the salt activity coefficient via:<ref>{{Cite book |last=Pitzer |first=Kenneth S. |url=https://www.eng.uc.edu/~beaucag/Classes/ChEThermoBeaucage/Books/Kenneth%20Sanborn%20Pitzer%20-%20Activity%20coefficients%20in%20electrolyte%20solutions-CRC%20Press%20(1991).pdf |title=Activity Coefficients in Electrolyte Solutions |publisher=CRC Press |year=2018}}</ref>

:<math>\phi = 1 + \frac{1}{m}\int_0^m md \left( \ln (\gamma_{\pm}) \right)</math>

Moreover, the activity coefficient of the salt <math>\gamma_{\pm}</math> can be calculated from:<ref>{{Cite book|last=Pitzer|first=Kenneth|title=Activity Coefficients in Electrolyte Solutions|last2=|first2=|publisher=[[CRC Press]]|year=1991|isbn=978-1-315-89037-1|pages=13}}</ref>

: <math>\ln (\gamma_{\pm}) = \phi-1+\int^m_0 \frac{\phi-1}{m} dm</math>


In [[ionic solution]]s, [[Debye-Hückel theory]] implies that <math>(\varphi - 1)\sum_i b_i</math> is [[asymptotic]] to <math>-\frac 2 3 A I^{3/2}</math>, where ''I'' is [[ionic strength]] and ''A'' is the Debye-Hückel constant (equal to about 1.17 for water at 25 °C). This means that, at least at low concentrations, the vapor pressure of the solvent will be greater than that predicted by Raoult's law. For instance, for solutions of [[magnesium chloride]], the [[vapor pressure]] is slightly greater than that predicted by Raoult's law up to a concentration of 0.7&nbsp;mol/kg, after which the vapor pressure is lower than Raoult's law predicts.
According to [[Debye–Hückel theory]], which is accurate only at low concentrations, <math display="inline"> (\phi - 1) \sum_i m_i</math> is [[asymptotic]] to <math display="inline"> -\frac 2 3 A I^{3/2}</math>, where ''I'' is [[ionic strength]] and ''A'' is the Debye–Hückel constant (equal to about 1.17 for water at 25&nbsp;°C).


For aqueous solutions, the osmotic coefficients can be calculated theoretically by [[Pitzer equations]]<ref name="davies">I. Grenthe and H. Wanner, ''Guidelines for the extrapolation to zero ionic strength'', http://www.nea.fr/html/dbtdb/guidelines/tdb2.pdf</ref> or TCPC model.<ref>{{cite journal|last1=Ge|first1=Xinlei|last2=Wang|first2=Xidong|last3=Zhang|first3=Mei|last4=Seetharaman|first4=Seshadri|title=Correlation and Prediction of Activity and Osmotic Coefficients of Aqueous Electrolytes at 298.15 K by the Modified TCPC Model|journal=Journal of Chemical & Engineering Data|volume=52|issue=2|year=2007|pages=538–547|issn=0021-9568|doi=10.1021/je060451k}}</ref><ref>{{cite journal|last1=Ge|first1=Xinlei|last2=Zhang|first2=Mei|last3=Guo|first3=Min|last4=Wang|first4=Xidong|title=Correlation and Prediction of Thermodynamic Properties of Nonaqueous Electrolytes by the Modified TCPC Model|journal=Journal of Chemical & Engineering Data|volume=53|issue=1|year=2008|pages=149–159|issn=0021-9568|doi=10.1021/je700446q}}</ref>
This means that, at least at low concentrations, the vapor pressure of the solvent will be greater than that predicted by Raoult's law. For instance, for solutions of [[magnesium chloride]], the [[vapor pressure]] is slightly greater than that predicted by Raoult's law up to a concentration of 0.7&nbsp;mol/kg, after which the vapor pressure is lower than Raoult's law predicts. For aqueous solutions, the osmotic coefficients can be calculated theoretically by [[Pitzer equations]]<ref name="davies">I. Grenthe and H. Wanner, ''Guidelines for the extrapolation to zero ionic strength'', http://www.nea.fr/html/dbtdb/guidelines/tdb2.pdf</ref> or TCPC model.<ref>{{cite journal|last1=Ge|first1=Xinlei|last2=Wang|first2=Xidong|last3=Zhang|first3=Mei|last4=Seetharaman|first4=Seshadri|title=Correlation and Prediction of Activity and Osmotic Coefficients of Aqueous Electrolytes at 298.15 K by the Modified TCPC Model|journal=Journal of Chemical & Engineering Data|volume=52|issue=2|year=2007|pages=538–547|issn=0021-9568|doi=10.1021/je060451k}}</ref><ref>{{cite journal|last1=Ge|first1=Xinlei|last2=Zhang|first2=Mei|last3=Guo|first3=Min|last4=Wang|first4=Xidong|title=Correlation and Prediction of Thermodynamic Properties of Nonaqueous Electrolytes by the Modified TCPC Model|journal=Journal of Chemical & Engineering Data|volume=53|issue=1|year=2008|pages=149–159|issn=0021-9568|doi=10.1021/je700446q}}</ref>
<ref>{{cite journal|last1=Ge|first1=Xinlei|last2=Zhang|first2=Mei|last3=Guo|first3=Min|last4=Wang|first4=Xidong|title=Correlation and Prediction of Thermodynamic Properties of Some Complex Aqueous Electrolytes by the Modified Three-Characteristic-Parameter Correlation Model|journal=Journal of Chemical & Engineering Data|volume=53|issue=4|year=2008|pages=950–958|issn=0021-9568|doi=10.1021/je7006499}}</ref><ref name="GeWang2009">{{cite journal|last1=Ge|first1=Xinlei|last2=Wang|first2=Xidong|title=A Simple Two-Parameter Correlation Model for Aqueous Electrolyte Solutions across a Wide Range of Temperatures†|journal=Journal of Chemical & Engineering Data|volume=54|issue=2|year=2009|pages=179–186|issn=0021-9568|doi=10.1021/je800483q}}</ref>
<ref>{{cite journal|last1=Ge|first1=Xinlei|last2=Zhang|first2=Mei|last3=Guo|first3=Min|last4=Wang|first4=Xidong|title=Correlation and Prediction of Thermodynamic Properties of Some Complex Aqueous Electrolytes by the Modified Three-Characteristic-Parameter Correlation Model|journal=Journal of Chemical & Engineering Data|volume=53|issue=4|year=2008|pages=950–958|issn=0021-9568|doi=10.1021/je7006499}}</ref><ref name="GeWang2009">{{cite journal|last1=Ge|first1=Xinlei|last2=Wang|first2=Xidong|title=A Simple Two-Parameter Correlation Model for Aqueous Electrolyte Solutions across a Wide Range of Temperatures†|journal=Journal of Chemical & Engineering Data|volume=54|issue=2|year=2009|pages=179–186|issn=0021-9568|doi=10.1021/je800483q}}</ref>


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* [[Law of dilution]]
* [[Law of dilution]]
* [[Thermodynamic activity]]
* [[Thermodynamic activity]]
* [[Ion transport number]]


==References==
==References==

Latest revision as of 12:12, 12 July 2024

An osmotic coefficient is a quantity which characterises the deviation of a solvent from ideal behaviour, referenced to Raoult's law. It can be also applied to solutes. Its definition depends on the ways of expressing chemical composition of mixtures.

The osmotic coefficient based on molality m is defined by:

and on a mole fraction basis by:

where is the chemical potential of the pure solvent and is the chemical potential of the solvent in a solution, MA is its molar mass, xA its mole fraction, R the gas constant and T the temperature in Kelvin.[1] The latter osmotic coefficient is sometimes called the rational osmotic coefficient. The values for the two definitions are different, but since

the two definitions are similar, and in fact both approach 1 as the concentration goes to zero.

Applications

[edit]

For liquid solutions, the osmotic coefficient is often used to calculate the salt activity coefficient from the solvent activity, or vice versa. For example, freezing point depression measurements, or measurements of deviations from ideality for other colligative properties, allows calculation of the salt activity coefficient through the osmotic coefficient.

Relation to other quantities

[edit]

In a single solute solution, the (molality based) osmotic coefficient and the solute activity coefficient are related to the excess Gibbs free energy by the relations:

and there is thus a differential relationship between them (temperature and pressure held constant):

Liquid electrolyte solutions

[edit]

For a single salt solute with molal activity (), the osmotic coefficient can be written as where is the stochiometric number of salt and the activity of the solvent. can be calculated from the salt activity coefficient via:[2]

Moreover, the activity coefficient of the salt can be calculated from:[3]

According to Debye–Hückel theory, which is accurate only at low concentrations, is asymptotic to , where I is ionic strength and A is the Debye–Hückel constant (equal to about 1.17 for water at 25 °C).

This means that, at least at low concentrations, the vapor pressure of the solvent will be greater than that predicted by Raoult's law. For instance, for solutions of magnesium chloride, the vapor pressure is slightly greater than that predicted by Raoult's law up to a concentration of 0.7 mol/kg, after which the vapor pressure is lower than Raoult's law predicts. For aqueous solutions, the osmotic coefficients can be calculated theoretically by Pitzer equations[4] or TCPC model.[5][6] [7][8]

See also

[edit]

References

[edit]
  1. ^ IUPAC, Compendium of Chemical Terminology, 2nd ed. (the "Gold Book") (1997). Online corrected version: (2006–) "osmotic coefficient". doi:10.1351/goldbook.O04342
  2. ^ Pitzer, Kenneth S. (2018). Activity Coefficients in Electrolyte Solutions (PDF). CRC Press.
  3. ^ Pitzer, Kenneth (1991). Activity Coefficients in Electrolyte Solutions. CRC Press. p. 13. ISBN 978-1-315-89037-1.
  4. ^ I. Grenthe and H. Wanner, Guidelines for the extrapolation to zero ionic strength, http://www.nea.fr/html/dbtdb/guidelines/tdb2.pdf
  5. ^ Ge, Xinlei; Wang, Xidong; Zhang, Mei; Seetharaman, Seshadri (2007). "Correlation and Prediction of Activity and Osmotic Coefficients of Aqueous Electrolytes at 298.15 K by the Modified TCPC Model". Journal of Chemical & Engineering Data. 52 (2): 538–547. doi:10.1021/je060451k. ISSN 0021-9568.
  6. ^ Ge, Xinlei; Zhang, Mei; Guo, Min; Wang, Xidong (2008). "Correlation and Prediction of Thermodynamic Properties of Nonaqueous Electrolytes by the Modified TCPC Model". Journal of Chemical & Engineering Data. 53 (1): 149–159. doi:10.1021/je700446q. ISSN 0021-9568.
  7. ^ Ge, Xinlei; Zhang, Mei; Guo, Min; Wang, Xidong (2008). "Correlation and Prediction of Thermodynamic Properties of Some Complex Aqueous Electrolytes by the Modified Three-Characteristic-Parameter Correlation Model". Journal of Chemical & Engineering Data. 53 (4): 950–958. doi:10.1021/je7006499. ISSN 0021-9568.
  8. ^ Ge, Xinlei; Wang, Xidong (2009). "A Simple Two-Parameter Correlation Model for Aqueous Electrolyte Solutions across a Wide Range of Temperatures†". Journal of Chemical & Engineering Data. 54 (2): 179–186. doi:10.1021/je800483q. ISSN 0021-9568.