Physical Chemistry Third Edition

(C. Jardin) #1

8.4 The Determination of Activities and Activity Coefficients of Electrolytes 371


8.4 The Determination of Activities and

Activity Coefficients of Electrolytes
These activity coefficients can be determined in several ways.

Determination by Vapor Pressure


In the case of a volatile electrolyte such as HCl or HNO 3 , the mean ionic activity
coefficient can be determined from the partial vapor pressure, using Eq. (7.4-12).

EXAMPLE 8.6

Using information in Example 7.15, find the value ofγ±for HCl at 10.00 mol kg−^1 and
298.15 K, in which case the partial vapor pressure of HCl is equal to 4.20 torr.a
Solution

γ^2 ±
P(HCl)
k±(m)m^2



(4.20 torr)

(
1 atm
760 torr

)

(4. 92 × 10 −^7 atm kg^2 mol−^2 )(10.00 mol kg−^1 )^2

 112

γ± 10. 6

aS. J. Bates and H. D. Kirschman,J. Am. Chem. Soc., 41 , 1991 (1919).

Activity Coefficients of Nonvolatile Electrolytes


The activities and activity coefficients of nonvolatile electrolytes can be determined
by the isopiestic method, as described in Chapter 6. They can also be determined
by electrochemical measurements. As an example consider the cell of Figure 8.2, for
which the Nernst equation is

EE◦−

RT

2 F

ln

(

a(HCl)^2
P(H 2 )/P◦

)

(8.4-1)

If the value ofE◦is known, the activity coefficient of HCl can then be determined
from the Nernst equation. Let us maintainP(H 2 ) equal toP◦and measure the
voltage at a molality of HCl equal tom. The Nernst equation can be written in
the form

lna(HCl)2ln

(

γ±m/m◦

)



F(E◦−E)

RT

(8.4-2)

EXAMPLE 8.7

In a cell such as that of Figure 8.2, a voltage of 0.3524 V was measured with a solution having
a molality of HCl equal to 0.1000 mol kg−^1 and a hydrogen pressure equal to 1.000 bar. Find
the value of the activity and of the mean ionic activity coefficient of HCl, assuming hydrogen
to be an ideal gas.
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