Physical Chemistry Third Edition

(C. Jardin) #1

6.7 Colligative Properties 297


Osmotic Pressure


This colligative property involves the equilibrium of a liquid solution and the pure
liquid solvent on opposite sides of a semipermeable membrane that allows only the
solvent to equilibrate. The equilibrium is achieved by having different pressures in
the two phases. A simple osmometer is shown in Figure 6.26. The left side of this
apparatus contains a solution containing a solute (component 2) dissolved in a solvent
(component 1), and the right side contains pure solvent. The pressure of the solution is
increased above that of the pure solvent by the gravitational (hydrostatic) force on the
solution in the left column.

PressureP

PressureP

PressureP1P

Solution Pure
solvent

Height of column giving hydrostatic pressure

Semipermeable
membrane with
rigid support

Figure 6.26 An Osmometer
(Schematic).

We denote the pressure on the pure solvent byP, and the pressure on the solution by
P+Π. The differenceΠis called theosmotic pressure. At equilibrium, the value of
the chemical potential of the solvent must be the same on both sides of the membrane.
If the solvent obeys Raoult’s law,

μ∗ 1 (T,P)μ 1 (T,P+Π)μ∗ 1 (T,P+Π)+RTln(x 1 ) (6.7-20)

we must abandon our previous approximation that the chemical potential is independent
of the pressure. From Eq. (5.4-10), if the molar volume of the pure liquid is nearly
independent of pressure (a good approximation),

μ∗ 1 (T,P+Π)−μ∗ 1 (T,P)

∫P+Π

P

Vm,1∗ dP≈ΠVm,1∗ (6.7-21)

which gives

ΠVm,1∗ −RTln(1−x 2 )≈RTx 2 (6.7-22)

It is customary to rewrite Eq. (6.7-22) in another form. For a dilute solution of two
components

x 2 

n 2
n 1 +n 2


n 2
n 1

and we can write

Vn 1 V ̄ 1 +n 2 V ̄ 2 ≈n 1 Vm,1∗

Use of these two equations gives

Π

n 2 RT
V

c 2 RT (6.7-23)

wherec 2 is the molar concentration of the solute. Equation (6.7-23) is one of two
equations known as thevan’t Hoff equation. It is remarkably similar to the ideal gas
equation of state.

The van’t Hoff equation is named for
Jacobus Henricus van’t Hoff,
1852–1911, a Dutch physical chemist
who won the 1901 Nobel Prize in
chemistry for his work on osmotic
pressure. He was also the first person
to propose the tetrahedral carbon atom. EXAMPLE6.20
The osmotic pressure of a moderately dilute solution can be surprisingly large. Find the
osmotic pressure at 25◦C of an aqueous solution of sucrose with a molar concentration of
0.200 mol L−^1.

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