Mayer's relation

Julius von Mayer derived a relation between specific heat at constant pressure and the specific heat at constant volume for an ideal gas. The relation is:

$C_{P,m}-C_{V,m}=R$ ,

where 'C_P,m' is the molar specific heat at constant pressure, 'C_V,m' is the specific heat at constant volume and R is the Universal Gas Constant.

For more general homogeneous substances, not just ideal gases, the difference takes the form,

C_{P}-C_{V}=VT{\frac {\alpha _{V}^{2}}{\beta _{T}}}\,

(see relations between heat capacities), where $C_{P}$ is the heat capacity of a body at constant pressure, $C_{V}$ is the heat capacity at constant volume, $V$ is the volume, $T$ is the temperature, $\alpha _{V}$ is the thermal expansion coefficient and $\beta$ is the isothermal compressibility.

From this relation, several inferences can be made:[1]

Since isothermal compressibility $\beta _{T}$ is positive for all phases and the square of thermal expansion coefficient ${\alpha }$ is a positive quantity or zero, the specific heat at constant-pressure is always greater than or equal to specific heat at constant-volume.

C_{P,m}

≥

C_{V,m}

As the absolute temperature of the system approaches zero, the difference between C_P,m and C_V,m also approaches zero.
For incompressible substances, C_P,m and C_V,m are identical. Also for substances that are nearly incompressible, such as solids and liquids, the difference between the two specific heats is negligible.

References

Boles, Yunus A. Çengel, Michael A. Thermodynamics : an engineering approach (7th ed.). New York: McGraw-Hill. ISBN 0-07-736674-3.

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[1] Boles, Yunus A. Çengel, Michael A. Thermodynamics : an engineering approach (7th ed.). New York: McGraw-Hill. ISBN 0-07-736674-3.