CK-12-Chemistry Intermediate

http://www.ck12.org Chapter 19. Equilibrium

Sample Problem 19.2: Calculating Ks pfrom Solubility

The solubility of lead(II) fluoride is found experimentally to be 0.533 g/L. Calculate the Ks pfor lead(II) fluoride.

Step 1: List the known quantities and plan the problem.

Known

• solubility of PbF 2 = 0.533 g/L


• molar mass of PbF 2 = 245.20 g/mol

Unknown

• Ks pof PbF 2 =?

The dissociation equation for PbF 2 and the corresponding Ks pexpression can be constructed as follows:

PbF 2 (s)⇀↽Pb^2 +(aq)+2F−(aq) Ksp= [Pb^2 +][F−]^2

The steps above will be followed to calculate Ks pfor PbF 2.

Step 2: Solve.

molar solubility:

0. (^533)
   g
   1 L

×

1 mol

245. 20 g

= 2. 17 × 10 −^3 M

The dissociation equation shows that, for every mole of PbF 2 that dissociates, 1 mol of Pb^2 +and 2 mol of F−are
produced. Therefore, at equilibrium, the concentrations of the ions are:

Pb^2 + = 2.17× 10 −^3 M and [F−] = 2×2.17× 10 −^3 = 4.35× 10 −^3 M

Substitute into the equilibrium expression, and solve for Ks p.

Ks p= (2.17× 10 −^3 )(4.35× 10 −^3 )^2 = 4.11× 10 −^8

Step 3: Think about your result.

The solubility product constant is significantly less than 1 for a nearly insoluble compound such as PbF 2.

Practice Problem

1. From the given solubility data, calculate Ks pfor each of the following compounds.
   a. copper(II) iodide, CuI = 4.30× 10 −^4 g/L
   b. silver sulfide, Ag 2 S = 2.84× 10 −^15 g/L

The known Ks pvalues from the table above (Table19.5) can be used to calculate the solubility of a given compound
by following the steps listed below.

1. Set up an ICE problem (Initial, Change, Equilibrium) in order to use the Ks pvalue to calculate the concentra-
   tion of each of the ions. Assume that no ions are initially present in the solution.


2. The concentrations of the ions can be used to calculate the molar solubility of the compound.