Mole fractions provide the most symmetrical way of representing thermodynamic functions of mixtures. For each component $i$, the mole fraction $x\_i$ is the number of moles $n\_i$ divided by the total number of moles in the system, $n$.

$x\_i\; \backslash equiv\; \backslash frac\{n\_i\}\{n\}\; =\; \backslash frac\{N\_i\}\{N\}$

where

$n\; =\; \backslash sum\_j\; n\_j\; \backslash ,$

The sum is over all components, including solvent in the case of a solution. As indicated above, the same ratio is obtained using the number of molecules of $i$, $N\_i$, and the total number of molecules of all kinds, $N$.

$N\_i\; =\; n\_i\; \backslash times\; N\_A$

where $N\_A$ is Avogadro's number ≈ 6.022 x 10²³. By definition, the sum of the mole fractions equals one, a normalization property.

$\backslash sum\_i\; x\_i\; \backslash equiv\; 1\; \backslash ,$

Mole fractions are one way of representing the concentrations of the various chemical species. They are an ideal-mixture approximation, and in practice, all measures of concentration must be multiplied by correction factors called activity coefficients in order to yield accurate results.

The mole fraction is sometimes denoted by the lower case Greek letter $\backslash chi$ (chi) instead of a Roman $x$.

All of the preceding numbers are dimensionless. Other ways of representing concentrations, e.g., molarity and molality, yield dimensional quantities (per litre, per kilogram, etc.). When chemical formulas seem to be taking the logarithms of dimensional quantities, there is an implied ratio, and such expressions can always be rearranged so that the arguments of the logarithms are dimensionless numbers, as they must be.

For mixtures of molecules of differing sizes, see: Volume fraction.

See also

• Parts per notation

Physical chemistry | Thermodynamics

Fractie (concentratie) | Fracción molar | モル分率 | Stoffmengenanteil