11.9 : Clausius-Clapeyron Equation

Recall that the vapor pressure of a liquid increases with a rise in temperature. However, this dependence is not linear.

To illustrate, the vapor pressure of water at 50 °C is 0.122 atm, while at 100 °C, it is 1 atm. Vapor pressure curves sharply upward with increasing temperature, resulting in an exponential curve.

In comparison, when the natural log of vapor pressure is plotted against reciprocal temperature, a straight line is obtained, and its equation is called the Clausius–Clapeyron equation.

Here, R is the ideal gas constant; c, a constant characteristic of the liquid, is the y-intercept; and the slope of the line is equal to the negative of the molar heat of vaporization over the gas constant.

The equation allows the calculation of the molar heat of vaporization from the experimental measurements of equilibrium vapor pressures and temperatures.

For example, suppose the natural log of ethanol vapor pressure plotted as a function of reciprocal temperature gives a straight line with the slope of negative 4638 kelvins.

The equation for the slope of the line, along with the value of R, gives the molar heat of vaporization of ethanol as 38 560 joules per mole.

If the molar heat of vaporization of any liquid and its vapor pressure at one temperature are known, the equation’s two-point form can be used to calculate the liquid’s vapor pressure at a different temperature.

Take the example of water, whose enthalpy of vaporization is 40.7 kilojoules per mole. If the vapor pressure of water at 373 kelvins is 1 atm, what will be its vapor pressure at 383 kelvins?

To solve, use the two-point form of the equation and substitute the given values of vapor pressure, enthalpy of vaporization, the two temperatures, and the gas constant to get the vapor pressure of water at 383 kelvins as 1.409 atm.

The rise in vapor pressure from 373 kelvins to 383 kelvins is 0.409 atm, which clearly indicates that an increase in vapor pressure as a function of temperature is a non-linear process.

The equilibrium between a liquid and its vapor depends on the temperature of the system; a rise in temperature causes a corresponding rise in the vapor pressure of its liquid. The Clausius-Clapeyron equation gives the quantitative relation between a substance’s vapor pressure (P) and its temperature (T); it predicts the rate at which vapor pressure increases per unit increase in temperature.

<div alt="Acetylide anion formation, equations, chemical reaction arrow, C–H acidic hydrogen, organic chemistry"></div>

where ΔH_vap is the enthalpy of vaporization for the liquid, R is the gas constant, and A is a constant whose value depends on the chemical identity of the substance. Temperature (T) must be in kelvin in this equation. However, since the relationship between vapor pressure and temperature is not linear, the equation is often rearranged into logarithmic form to yield the linear equation:

Static equilibrium diagram with force vectors and conditions ΣFx=0, ΣFy=0; mechanical balance illustration.

For any liquid, if the enthalpy of vaporization and vapor pressure at a particular temperature is known, the Clausius-Clapeyron equation allows to determine the liquid’s vapor pressure at a different temperature. To do this, the linear equation may be expressed in a two-point format. If at temperature T₁, the vapor pressure is P₁, and at temperature T₂, the vapor pressure is P₂, the corresponding linear equations are:

Static equilibrium equations ΣFx=0 diagram; forces, vectors, equilibrium analysis, engineering mechanics.

Since the constant, A, is the same, these two equations may be rearranged to isolate ln A and then set them equal to one another:

Static equilibrium diagram, ΣFx=0, MA=0, showing forces and moments in a balanced beam system.

which can be combined into:

Pascal's Triangle diagram illustrating binomial coefficients and combinatorial equations.

This text is adapted from Openstax, Chemistry 2e, Section 10.3: Phase Transitions.

Tags

Clausius Clapeyron Equation Vapor Pressure Temperature Dependence Exponential Curve Natural Log Straight Line Ideal Gas Constant Molar Heat Of Vaporization Equilibrium Vapor Pressures Experimental Measurements Reciprocal Temperature Ethanol Vapor Pressure Slope Of The Line Joules Per Mole Two point Form

From Chapter 11:

Now Playing

11.9 : Clausius-Clapeyron Equation

Liquids, Solids, and Intermolecular Forces

56.9K Views

11.1 : Molecular Comparison of Gases, Liquids, and Solids

Liquids, Solids, and Intermolecular Forces

41.3K Views

11.2 : Intermolecular vs Intramolecular Forces

Liquids, Solids, and Intermolecular Forces

87.5K Views

11.3 : Intermolecular Forces

Liquids, Solids, and Intermolecular Forces

58.5K Views

11.4 : Comparing Intermolecular Forces: Melting Point, Boiling Point, and Miscibility

Liquids, Solids, and Intermolecular Forces

44.4K Views

11.5 : Surface Tension, Capillary Action, and Viscosity

Liquids, Solids, and Intermolecular Forces

27.9K Views

11.6 : Phase Transitions

Liquids, Solids, and Intermolecular Forces

19.1K Views

11.7 : Phase Transitions: Vaporization and Condensation

Liquids, Solids, and Intermolecular Forces

17.6K Views

11.8 : Vapor Pressure

Liquids, Solids, and Intermolecular Forces

35.0K Views

11.10 : Phase Transitions: Melting and Freezing

Liquids, Solids, and Intermolecular Forces

12.4K Views

11.11 : Phase Transitions: Sublimation and Deposition

Liquids, Solids, and Intermolecular Forces

17.2K Views

11.12 : Heating and Cooling Curves

Liquids, Solids, and Intermolecular Forces

22.9K Views

11.13 : Phase Diagrams

Liquids, Solids, and Intermolecular Forces

41.1K Views

11.14 : Structures of Solids

Liquids, Solids, and Intermolecular Forces

14.2K Views

11.15 : Molecular and Ionic Solids

Liquids, Solids, and Intermolecular Forces

17.2K Views

See More