The molar volume of a substance i is defined as its
molar mass divided by its density ρi0:
For an
ideal mixture containing N components, the molar volume of the mixture is the
weighted sum of the molar volumes of its individual components. For a real mixture the molar volume cannot be calculated without knowing the density:
There are many liquid–liquid mixtures, for instance mixing pure
ethanol and pure
water, which may experience contraction or expansion upon mixing. This effect is represented by the quantity excess volume of the mixture, an example of
excess property.
Relation to specific volume
Molar volume is related to
specific volume by the product with
molar mass. This follows from above where the specific volume is the
reciprocal of the density of a substance:
Ideal gases
For
ideal gases, the molar volume is given by the
ideal gas equation; this is a good approximation for many common gases at
standard temperature and pressure.
The ideal gas equation can be rearranged to give an expression for the molar volume of an ideal gas:
Hence, for a given temperature and pressure, the molar volume is the same for all ideal gases and is based on the
gas constant: R = 8.31446261815324 m3⋅Pa⋅K−1⋅mol−1, or about 8.20573660809596×10−5 m3⋅atm⋅K−1⋅mol−1.
The molar volume of an ideal gas at 100
kPa (1
bar) is
0.022710954641485... m3/mol at 0 °C,
0.024789570296023... m3/mol at 25 °C.
The molar volume of an ideal gas at 1 atmosphere of pressure is
0.022413969545014... m3/mol at 0 °C,
0.024465403697038... m3/mol at 25 °C.
Crystalline solids
For
crystalline solids, the molar volume can be measured by
X-ray crystallography.
The
unit cell volume (Vcell) may be calculated from the
unit cell parameters, whose determination is the first step in an X-ray crystallography experiment (the calculation is performed automatically by the structure determination software). This is related to the molar volume by
where NA is the
Avogadro constant and Z is the number of formula units in the unit cell. The result is normally reported as the "crystallographic density".
Ultra-pure
silicon is routinely made for the
electronics industry, and the measurement of the molar volume of silicon, both by X-ray crystallography and by the ratio of molar mass to mass density, has attracted much attention since the pioneering work at
NIST in 1974.[2] The interest stems from that accurate measurements of the unit cell volume,
atomic weight and mass density of a pure crystalline solid provide a direct determination of the Avogadro constant.[3]
The CODATA recommended value for the molar volume of silicon is 1.205883199(60)×10−5 m3⋅mol−1, with a relative standard uncertainty of 4.9×10−8.[4]