5 Steps to a 5 AP Chemistry

The equilibrium constant expression is called the weak base dissociation constant, Kb,
and has the form:

The same reasoning that was used in dealing with weak acids is also true here: [HB+] =
[OH−]; [HB] ≈Minitially; the numerator can be represented as [OH−]^2 ; and knowing the ini-
tial molarity and Kbof the weak base, the [OH−] can easily be calculated. And if the initial
molarity and [OH−] are known, Kbcan be calculated.
For example, a 0.500 M solution of ammonia has a pH of 11.48. What is the Kbof
ammonia?

pH =11.48

[H+] = 10 −11.48

[H+] =3.3 × 10 −^12 M

Kw=[H+][OH−] =1.0 × 10 −^14

[OH−] =3.0 × 10 −^3 M

0.500 − xxx

[OH−] =[NH 4

+

] =3.0 × 10 −^3 M

[NH 3 ] =0.500 − 3.0 × 10 −^3 =0.497 M

The Kaand Kbof conjugate acid–base pairs are related through the Kwexpression:

Ka×Kb=Kw

This equation shows an inverse relationship between Kaand Kbfor any conjugate
acid–base pair.
This relationship may be used in problems such as: Determine the pH of a solution
made by adding 0.400 mol of strontium acetate to sufficient water to produce 2.000 L of
solution.
Solution:
The initial molarity is 0.400 mol/2.000 L =0.200 M.
When a salt is added to water dissolution will occur:

Sr (C H O 232 )( 22 →Sr2+aq) + 2C H O aq) 23 −(

Kb=

×

=×

−

(. ) −

(. )

.

30 10

0 497

18 10

32

5

Kb^4

NH+ OH

NH

=

[][]−

[] 3

NH 32 ++H ONH+− 4 OH

Kb

HB OH

HB]

+

=

[][ ]−

[

Equilibrium  221