Title: Chapter 18 Solubility and Complex-Ion Equilibria
1Chapter 18 Solubility and Complex-Ion Equilibria
- Dr. Peter Warburton
- peterw_at_mun.ca
- http//www.chem.mun.ca/zcourses/1051.php
2Solubility equilibria
- MmXx (s) ? m Mn (aq) x Xy- (aq)
- The equilibrium is established when we have a
saturated solution of ions forming the solid and
solid is dissociating to form the ions in
solution. The rates of these processes must be
equal. (eqm definition)
3Solubility equilibria
- For a dissolution process, we give the
equilibrium constant expression the name
solubility product (constant) Ksp. For - MmXx (s) ? m Mn (aq) x Xy- (aq)
- Ksp Mnm Xy-x
4Ksp is an equilibrium constant
- Since Ksp is an equilibrium constant we MUST
- refer to a specific balanced equation
- (by definition this balanced equation is one mole
of solid becoming aqueous ions) - at a specific temperature.
5Problem
- Write the expressions of Ksp of
- a) AgCl
- b) PbI2
- c) Ca3(PO4)2
- d) Cr(OH)3
6(No Transcript)
7Problem
- If a saturated solution of BaSO4 is prepared by
dissolving solid BaSO4 in water, and Ba2
1.05 x 10-5 mol?L-1, what is the Ksp for BaSO4?
8Molar solubility
- If we know the Ksp value for a solid, we can
calculate the molar solubility, which is the
number of moles of the solid that can dissolve in
a given amount of solvent before the solution
becomes saturated. - The molar solubility leads to the solubility (by
using the molar mass) which is the mass of the
solid that can dissolve in a given amount of
solvent before the solution becomes saturated.
9Molar solubility
- Alternatively, if we know the
- molar solubility
- OR
- the molar mass and the solubility
- we can calculate
- the Ksp for the solid.
10Molar solubility
- A good (but NOT physically correct) way to think
about molar solubility is to treat our solid
dissolution AS IF there are two separate
processes - The molar solubility has the same value as the
concentration of aqueous MmXx after the first
step. We can figure out this concentration based
on concentrations of ions in the second step.
11Problem
- A handbook lists the aqueous solubility of AgOCN
as 7 mg per 100 mL at 20 ?C. What is the Ksp of
AgOCN at 20 ?C? The molar mass of AgOCN is
149.885 g?mol-1.
Answer Ksp 2 x 10-7
12Problem
- A handbook lists the aqueous solubility of
lithium phosphate (Li3PO4) as 0.034 g per 100 mL
at 18 ?C. What is the Ksp of lithium phosphate
at 18 ?C? The molar mass of Li3PO4 is 115.794
g?mol-1.
Answer Ksp 2.0 x 10-9
13Problem
- Which has the greater molar solubility
- AgCl with Ksp 1.8 x 10-10
- or
- Ag2CrO4 with Ksp 1.1 x 10-12?
Answer The molar solubility of AgCl is 1.3 x
10-5 M while the molar solubility of Ag2CrO4 is
6.5 x 10-5 M. Silver chromate has a higher molar
solubility.
14Problem
- How many milligrams of BaSO4 (molar mass is
233.391 g?mol-1) are dissolved in a 225 mL sample
of saturated aqueous barium sulphate? Ksp 1.1
x 10-10 at 25 ?C.
Answer mass 0.55 mg
15The common-ion effect
- MmXx (s) ? m Mn (aq) x Xy- (aq)
- If we have dissolved a solid in pure water and we
add to this solution another solution containing
one of the common ions, then Le Chataliers
Principle tells us what will happen - The presence of the common-ion in the added
solution will force the dissolution reaction to
the left, meaning more solid will form!
16The common-ion effect
17Figure
18The common-ion effect
- MmXx (s) ? m Mn (aq) x Xy- (aq)
- If instead of dissolving a solid in pure water we
try and dissolve it into a solution that already
contains one of the common ions, then Le
Chataliers Principle tells us what will happen - The presence of the common-ion already in
solution will force the dissolution reaction to
the left, meaning less solid will dissolve than
would dissolve in pure water!
19(No Transcript)
20Problem
- Calculate the molar solubility of MgF2 (Ksp 7.4
x 10-11) in pure water and in 0.10 mol?L-1 MgCl2
at 25 C.
Answer The molar solubility is 2.6 x 10-4 M in
pure water and 1.4 x 10-5 M in 0.10 M magnesium
chloride.
21Problem
- What is the the molar solubility of Fe(OH)3 (Ksp
4 x 10-38) in a buffered solution with pH
8.20 at 25 C.
Answer The molar solubility is 1 x 10-20 M in
the buffered solution.
22Limitations of Ksp
- If our solid is more than slightly soluble then
we really should use the activities of our ions
in solution rather than concentrations. - These two measures are nearly the same for very
dilute ion concentrations, but can become quite
different at higher concentrations!
23The diverse (uncommon) ion effect
- The activities of ions tend to be LESS than the
concentration value as the total ionic
concentration increases.
24The diverse (uncommon) ion effect
- Adding a salt that does NOT feature a common ion
to the solution will tend to decrease the
activity (the effective concentration) of the
ions in solution. - The ion concentrations appear smaller than they
should be at equilibrium so more solid dissolves
to reach the appropriate equilibrium
concentrations.
25(No Transcript)
26Ion-pair formation and Ksp
- We assume in Ksp calculations that the solid
dissociates completely into ions in solution. - If this is not true, then the ionic
concentrations we measure do not include
dissolved but undissociated molecules or ion
pairs which come from solid dissolution.
27Ion-pair formation and Ksp
- Positive ions and negative ions are attracted to
each other and so they can form an ion pair that
has a chemical identity different from each of
the individual ions!
28Ion-pair formation and Ksp
- Say we measure a molar solubility for magnesium
fluoride to be 4 x 10-3 M and assume that - Mg2 4 x 10-3 M and
- F- 8 x 10-3 M
- to give a
- calculated Ksp of 3 x 10-7
29Ion-pair formation and Ksp
- IN REALITY the presence of undissociated MgF2
(aq) - and MgF- ion pairs
- means that not all of the solid that has
dissolved is found as free ions, so our ionic
concentrations are LOWER than we assumed, and so
Ksp is actually smaller than we calculated.
30Simultaneous equilibria
- Weve seen in reference to Le Chataliers
Principle that if more than one reaction can take
place in a container, then the reactions might
not be able to be treated independently. Other
equilibrium processes may affect the solubility
of the solid and lead to miscalculated Ksp values.
31Simultaneous equilibria
- For example, weve seen that AgI becomes more
soluble when we add ammonia because of the
formation of a complex of silver ions and
ammonia. - Well look more closely at complex formation a
little later.
32Assessing the limitations of Ksp
- Most tabulated Ksp values are actually based on
activities, and not concentrations. - We use concentrations in our examples, so our
calculations represent an ideal, and not reality.
- Generally we could be in error by over 100 times!
33Criteria for precipitation and its completeness
- Can we predict if a solid will form if we mix two
solutions of different ions? - Consider the mixing of two different solutions,
one with Ca2 ions and one with F- ions. A
formation of solid is the dissolution reaction in
reverse, so we can express the reaction using the
dissolution equation - CaF2 (s) ? Ca2 (aq) 2 F- (aq) Ksp Ca2
F-2
34Criteria for precipitation and its completeness
- When we mix the solutions
- (BE CAREFUL mixing ALWAYS changes the
concentrations of both our ions!) - the system is most likely not at equilibrium.
- Like in other equilibrum problems, we can use a
reaction quotient Qsp (often called the ion
product) to tell us in which direction the system
must go to reach equilibrium - Qsp Ca2 F-2
35Criteria for precipitation and its completeness
If Qsp gt Ksp, the solution is supersaturated, so
the system is not at equilibrium. The
concentration of the ions is greater than it
would be at equilibrium, and so the reaction
wants to shift from ions towards the solid. We
expect precipitation to occur! If Qsp Ksp, the
solution is saturated, and the system is at
equilibrium. No precipitation occurs!
36Criteria for precipitation and its completeness
If Qsp lt Ksp, the solution is unsaturated, so the
system is not at equilibrium. The concentration
of the ions is less than it would be at
equilibrium, and so the reaction wants to shift
from solid towards the ions. No precipitation
can occur!
37Mixing and equilibrium take time!
We must wait until dilution is completed and
equilibrium is established BEFORE we say
precipitation occurred!
38Problem
- Will a precipitate form when 0.150 L of 0.10
mol?L-1 Pb(NO3)2 and 0.100 L of 0.20 mol?L-1 NaCl
are mixed? - Ksp of PbCl2 is 1.2 x 10-5
Answer Qsp 3.8 x 10-4 gt Ksp so precipitation
should occur.
39Problem
- How many drops (1 drop 0.05 mL) of 0.20 M KI
must we add to 100.0 mL of 0.010 M Pb(NO3)2 to
get precipitation of lead iodide to start? - Ksp of PbI2 is 7.1 x 10-9
Answer We require at least 9 drops.
40Complete precipitation
- Generally we treat precipitation as complete if
99.9 of the original ion concentration has been
lost to the precipitate. - For example, if our initial Pb2 is 0.10 M,
then precipitation by adding I- is complete when
our solution contains a Pb2 less than 1 x 10-4
M.
41Problem
- A typical Ca2 concentration in seawater is 0.010
M. Will the precipitation of Ca(OH)2 be complete
from a seawater sample in which OH- is
maintained at 0.040 M? - Ksp of Ca(OH)2 is 5.5 x 10-6
Answer Since the final Ca2 is 3.4 x 10-3 M,
which is 34 of 0.010 M, the precipitation is
not complete.
42Problem
- What OH- should be maintained in a solution if,
after precipitation of Mg2 as solid magnesium
hydroxide, the remaining Mg2 is to be at a
level of 1?g?L-1? - Molar mass Mg is 24.305 g?mol-1
- Ksp of Mg(OH)2 is 1.8 x 10-11
Answer OH- needed is 1.6 x 10-2 M.
43Fractional precipitation
- If we have a solution with
- both CrO42- ions and Br- ions
- and add a large amount of Ag ions at once,
- then both Ag2CrO4 and AgBr
- will precipitate
- in our container at the same time.
44Fractional precipitation
- If we slowly add the Ag solution instead the
solid with the significantly lower molar
solubility (AgBr in this case do the
calculations to check this for yourself) - will precipitate first
- and consume the added Ag preferentially.
45Fractional precipitation
- In other words,
- the concentration of Ag
- CAN NOT become large enough
- to precipitate Ag2CrO4
- until the AgBr
- precipitation is complete.
46Fractional precipitation
47Problem
- AgNO3 is slowly added to a solution with Cl-
0.115 M and Br- 0.264 M. What percent of the
Br- remains unprecipitated at the point at which
AgCl (s) begins to precipitate? - Ksp values
- AgCl 1.8 x 10-10 AgBr 5.0 x 10-13
Answer 0.12 of Br- remains.
48Solubility and pH
- If a solid dissolves to give a basic anion in
solution, addition of strong acid will increase
the solubility of the solid. - CaCO3 (s) ? Ca2 (aq) CO32- (aq) Ksp 2.8 x
10-9 - Carbonate, CO32-, is a basic anion that will
react with a proton to give HCO3- - CO32- (aq) H3O (aq) ? HCO3- (aq) H2O (l)
49Solubility and pH
- CO32- (aq) H3O (aq) ? HCO3- (aq) H2O (l)
- This reaction will shift to the right (products)
as the pH becomes more acidic which means CO32-
(aq) decreases. However, in our first
equilibrium IT ALSO MUST DECREASE so the first
equilibrium will also shift to the right to
compensate. - More solid will dissolve!
50(No Transcript)
51Adding equilibria
- A better way to state the effect of pH on
solubility comes when we add dissolution and weak
base strong acid reactions together - CaCO3 (s) ? Ca2 (aq) CO32- (aq)
- Ksp 2.8 x 10-9
- CO32- (aq) H3O (aq) ? HCO3- (aq) H2O (l)
- K Kb x 1/Kw (2.1 x 10-4) x (1.0 x 1014)
- K 2.1 x 1010
52Adding equilibria
- CaCO3 (s) H3O (aq) ?
- Ca2 (aq) HCO3- (aq) H2O (l)
- K K x Ksp (2.1 x 1010) x (2.8 x 10-9)
- K 59
- The solubility of the solid will increase in the
presence of H3O!
53Problem
- Will a precipitate of Fe(OH)3 form from a
solution that is 0.013 M Fe3 in a buffer
solution that is 0.150 M acetic acid 0.250 M
acetate? - Ksp Fe(OH)3 4 x 10-38 Ka 1.8 x 10-5
Answer Since Qsp is 1 x 10-29, then
precipitation will occur since QspgtKsp.
54Problem
- What minimum NH4 must be present to prevent
precipitation of Mn(OH)2 (s) from a solution that
is 0.0050 M MnCl2 and 0.025 M NH3? For Mn(OH)2
Ksp 1.9 x 10-13 and Kb for NH3 is 1.8 x 10-5.
Answer NH4 gt 0.073 M
55Formation of complex ions
- Solubility of a solid increases if there is the
ability to form a complex ion. - An example of a complex ion is Ag(NH3)2.
- Such complexes affect solubility by reducing the
concentration of the cation so that the
dissolution reaction must shift to the products
to replace the cation concentration to
re-establish equilibrium.
56Formation of complex ions
- Ag (aq) 2 NH3 (aq) ? Ag(NH3)2 (aq) Kf 1.7
x 107 -
- AgCl (s) ? Ag (aq) Cl- (aq) Ksp 1.8 x
10-10 -
- In the presence of ammonia, the dissolution of
AgCl can be expressed by the sum of these two
reactions - 2 NH3 (aq) AgCl (s) ? Ag(NH3)2 (aq) Cl- (aq)
- K Kf x Ksp 1.7 x 107 x 1.8 x 10-10 3.1 x
10-3
57Formation of complex ions
- We see the dissolution of AgCl occurs to a
greater level of completion - in the presence of ammonia
- (K 3.1 x 10-3)
- than it does in pure water
- (Ksp 1.8 x 10-10).
58(No Transcript)
59Qualitative cation analysis
- Qualitative analysis is concerned with what do
we have? and NOT how much do we have? - If we want to identify what cations we have in a
solution, we can use a series of precipitation
reactions in a certain order to tell us.
60(No Transcript)
61Groups of precipitated ions
- 1) Chloride group
- Pb2, Ag, Hg22
- 2) Hydrogen Sulphide group-
- Pb2, Hg2, Bi3, Cu2, Cd2, As3, Sn2, Sb3
- 3) Ammonium sulphide group
- Mn2, Fe2, Fe3, Ni2, Co2, Al3, Zn2, Cr3
- 4) Carbonate group
- Mg2, Ca2, Sr2, Ba2
- 5) Soluble group
- Na, K, NH4
62Reactions with hydrogen chloride
- Most metal ions form soluble salts with chloride
EXCEPT Pb2, Hg22, and Ag. Adding aqueous HCl
to our unknown solution will let us now if we
have one or more of these ions because we will
get white precipitate(s). If we want to know if
we have more than one of these ions, we do
further tests on the precipitated solids
63Further tests for insoluble chlorides
- In a) we have a mixture of AgCl, Hg2Cl2, and
PbCl2. - If we add ammonia, any AgCl should dissolve
because of complex ion formation - AgCl (s) 2 NH3 (aq) ?
- Ag(NH3)2 (aq) Cl- (aq)
64Further tests for insoluble chlorides
- Also after adding ammonia (b), any Hg2Cl2 will
give us a grey solid that is a mixture of black
liquid Hg and white solid HgNH2Cl - Hg2Cl2 (s) 2 NH3 (aq) ?
- Hg (l) HgNH2Cl (s) NH4Cl (aq)
- black white
65Further tests for insoluble chlorides
- Adding chromate (CrO42-) (c) to a Pb2 solution
derived by heating the precipitate solutions
(its the most soluble) will give a yellow
precipitate - PbCrO4 - Pb2 (aq) CrO42- (aq) ?
- PbCrO4(s)
-
66Reactions with hydrogen sulfide
- S2- is capable of giving precipitates of many
ions. - H2S is a potential source of S2- in solution
because it is a diprotic acid - H2S (aq) H2O (l) ? H3O (aq) HS- (aq)
- Ka1 1.0 x 10-7
- HS- (aq) H2O (l) ? H3O (aq) S2- (aq)
- Ka2 1 x 10-19
67Reactions with hydrogen sulfide
- However, in acidic solution (with HCl), some of
the precipitates dissolve, leaving behind - PbS, HgS, Bi2S3, CuS, CdS, As2S3, SnS, Sb2S3
- In basic solution (by adding ammonia) these
precipitates dissolve, leaving behind - MnS, FeS, Fe(OH)3, NiS, CoS, Al(OH)3, ZnS, Cr(OH)3
68Reactions with carbonate
- Addition of carbonate ion (CO32-) in basic
solution (usually with an ammonia-ammonium
buffer) will precipitate the alkali earth metal
carbonates (see Chapter 21) - CaCO3, MgCO3, SrCO3, BaCO3
69The soluble group
- Any ions left in solution after the first four
reaction groups are tested for are the cations of
soluble salts - Na, K, and NH4