The
Clausius–Clapeyron relation, named after
Rudolf Clausius[1] and
Benoît Paul Émile Clapeyron,
[2] is a way of characterizing a discontinuous
phase transition between two
phases of matter of a single constituent. On a
pressure–
temperature (P–T) diagram, the line separating the two phases is known as the coexistence curve. The Clausius–Clapeyron relation gives the
slope of the
tangents to this curve. Mathematically,
where
is the slope of the tangent to the coexistence curve at any point,
is the specific
latent heat,
is the
temperature,
is the
specific volume change of the phase transition, and
is the
specific entropy change of the phase transition.
Derivations
A typical phase diagram. The dotted green line gives the anomalous behavior of water. The Clausius–Clapeyron relation can be used to find the relationship between pressure and temperature along phase boundaries.
Derivation from state postulate
Using the
state postulate, take the
specific entropy for a homogeneous substance to be a function of
specific volume and
temperature .
[3]:508
The Clausius–Clapeyron relation characterizes behavior of a
closed system during a
phase change, during which temperature and
pressure are constant by definition. Therefore,
[3]:508
Using the appropriate
Maxwell relation gives
[3]:508
where
is the pressure. Since pressure and temperature are constant, by definition the derivative of pressure with respect to temperature does not change.
[4][5]:57, 62, 671 Therefore, the
partial derivative of specific entropy may be changed into a
total derivative
and the total derivative of pressure with respect to temperature may be
factored out when
integrating from an initial phase
to a final phase
,
[3]:508 to obtain
where
and
are respectively the change in specific entropy and specific volume. Given that a phase change is an internally
reversible process, and that our system is closed, the
first law of thermodynamics holds
where
is the
internal energy of the system. Given constant pressure and temperature (during a phase change) and the definition of
specific enthalpy , we obtain
Given constant pressure and temperature (during a phase change), we obtain
[3]:508
Substituting the definition of
specific latent heat gives
Substituting this result into the pressure derivative given above (
), we obtain
[3]:508[6]
This result (also known as the
Clapeyron equation) equates the slope of the tangent to the
coexistence curve , at any given point on the curve, to the function
of the specific latent heat
, the temperature
, and the change in specific volume
.
Derivation from Gibbs–Duhem relation[edit]
Suppose two phases,
and
, are in contact and at equilibrium with each other. Their chemical potentials are related by
Furthermore, along the
coexistence curve,
One may therefore use the
Gibbs–Duhem relation
(where
is the specific
entropy,
is the
specific volume, and
is the
molar mass) to obtain
Rearrangement gives
from which the derivation of the Clapeyron equation continues as in
the previous section.
Ideal gas approximation at low temperatures
When the
phase transition of a substance is between a
gas phase and a condensed phase (
liquid or
solid), and occurs at temperatures much lower than the
critical temperature of that substance, the
specific volume of the gas phase
greatly exceeds that of the condensed phase
. Therefore, one may approximate
at low
temperatures. If
pressure is also low, the gas may be approximated by the
ideal gas law, so that
where
is the pressure,
is the
specific gas constant, and
is the temperature. Substituting into the Clapeyron equation
we can obtain the
Clausius–Clapeyron equation[3]:509
for low temperatures and pressures,
[3]:509 where
is the
specific latent heat of the substance.
Let
and
be any two points along the
coexistence curve between two phases
and
. In general,
varies between any two such points, as a function of temperature. But if
is constant,
or
[5]:672
These last equations are useful because they relate
equilibrium or
saturation vapor pressure and temperature to the latent heat of the phase change,
without requiring specific volume data.
Applications
Chemistry and chemical engineering
For transitions between a gas and a condensed phase with the approximations described above, the expression may be rewritten as
where
is a constant. For a liquid-gas transition,
is the
specific latent heat (or
specific enthalpy) of
vaporization; for a solid-gas transition,
is the specific latent heat of
sublimation. If the latent heat is known, then knowledge of one point on the
coexistence curve determines the rest of the curve. Conversely, the relationship between
and
is linear, and so
linear regression is used to estimate the latent heat.
Meteorology and climatology
Atmospheric water vapor drives many important
meteorologic phenomena (notably
precipitation), motivating interest in its
dynamics. The Clausius–Clapeyron equation for water vapor under typical atmospheric conditions (near
standard temperature and pressure) is
where:
The temperature dependence of the latent heat
, and therefore of the saturation vapor pressure
,
cannot be neglected in this application. Fortunately, the
August-Roche-Magnus formula provides a very good approximation, using pressure in
hPa and temperature in
Celsius:
- [7][8]
(This is also sometimes called the
Magnus or
Magnus-Tetens approximation, though this attribution is historically inaccurate.
[9])
Under typical atmospheric conditions, the
denominator of the
exponent depends weakly on
(for which the unit is Celsius). Therefore, the August-Roche-Magnus equation implies that saturation water vapor pressure changes approximately
exponentially with temperature under typical atmospheric conditions, and hence the water-holding capacity of the atmosphere increases by about 7% for every 1 °C rise in temperature.
[10]
Example
One of the uses of this equation is to determine if a phase transition will occur in a given situation. Consider the question of how much pressure is needed to melt ice at a temperature
below 0 °C. Note that water is unusual in that its change in volume upon melting is negative. We can assume
and substituting in
- = 3.34×105 J/kg (latent heat of fusion for water),
- = 273 K (absolute temperature), and
- = −9.05×10−5 m³/kg (change in specific volume from solid to liquid),
we obtain
- = −13.5 MPa/K.
To provide a rough example of how much pressure this is, to melt ice at −7 °C (the temperature many
ice skating rinks are set at) would require balancing a small car (mass = 1000 kg
[11]) on a
thimble (area = 1 cm²).
Second derivative
While the Clausius–Clapeyron relation gives the slope of the coexistence curve, it does not provide any information about its curvature or second derivative. The second derivative of the coexistence curve of phases 1 and 2 is given by
[12]
where subscripts 1 and 2 denote the different phases,
is the specific
heat capacity at constant pressure,
is the
thermal expansion coefficient, and
is the
isothermal compressibility.