Physical Properties of Solutions

Aqueous Solutions

Topics

1.  Electrolytes

2.  Concentration and Dilution

3.  Solubility Rules and Precipitation Reactions

4.  Acid-Base Reactions

5.  Oxidation-Reduction (Redox) Reactions

1. Oxidation numbers
2. Agents and half–reactions
3. Activity series

6.  Solution Stoichiometry

1. Gravimetric analysis
2. Acid-base titration

Topic 1 – Electrolytes

Electrolytes are substance that will form electrically conductive solutions. The conductivity is proportional to the number of ions produced when the substance is dissolved. Strong electrolytes dissolve with virtually 100% of the compound dissociated into ions. Non-electrolytes dissolve with virtually none of the compound dissociated. Weak electrolytes form an equilibrium relationship between dissociated ions and the parent compound when dissolved.

Example 1:  Compound Description Notes

NaCl strong electrolyte Very soluble, 100% dissociation

Ba(OH)2 strong electrolyte Sparingly soluble, but no Ba(OH)2(aq)

Sugar non-electrolyte Dissolves as molecule, no dissociation

SiO2 (glass) non-electrolyte Does not dissolve at all

Or,

NaCl(s) Û Na+(aq) + Cl-(aq)

Ba(OH)2(s) Û Ba2+(aq) + OH-(aq)

C6H12O6(s) Û C6H12O6(aq)

SiO2(s) Û SiO2(s) (not soluble)

Topic 2 – Concentration and Dilution

Concentration is the ratio of amount of solute to amount of solution (or solvent). The amounts can be measured in a variety of ways but the most common is solute in moles and solution in liters. This is concentration expressed as Molarity:

Example 2:  What is the concentration of a solution made by diluting 3.57 g NaOH to 2.00 L?

M = ? = 4.46 x 10-2 M

N = 3.57 g x 1 mol/40.00 g = 0.0892 mol

V = 2.00 L

Example 3:  What volume of 0.050 M NaCl can be made from 75.0 g of NaCl?

M = 0.050 M = 0.050 mol·L-1

N = 75.0 g x 1 mol/58.44 g = 1.28 mol

V = ? = 25.6 L ≈ 26 L

If I dilute a solution, it still has the same number of moles of solute as before the dilution. Based on M=n/V,

Example 4:  How much 3.00 M HCl do I need to make 2.00 L of 0.10 M HCl?

M1 = 3.00 M M1V1 = M2V2

V1 = ?

M2 = 0.10 M V1 = M2V2/ M1

V2 = 2.00 L

Topic 3 – Precipitation Reactions

When two solutions are combined, the dissolved electrolytes of one solution have the opportunity to react with electrolytes of the other solution. If the resulting product is also soluble, it will simply stay dissolved. We say it did not react. Alternatively, the resulting product may be insoluble and precipitate. You must be able to recognize precipitation reactions by memorizing the following solubility rules:

Example 5:  What happens if a solution of magnesium nitrate is mixed with a solution of sodium hydroxide?

Magnesium nitrate and sodium hydroxide are both soluble (given in the question) because according to the rules, all nitrates and all sodium salts are soluble. Thus the reactants can be written as follows:

Na+(aq) + OH-(aq) + Mg2+(aq) + NO3-(aq) →

The possibilities for a double replacement reaction are: NaNO3 and Mg(OH)2

However, according to the solubility rules, all nitrates are soluble and all hydroxides are insoluble (Mg is not one of the exceptions). Thus, the complete ionic reaction is:

Na+(aq) + OH-(aq) + NO3-(aq) → Na+(aq) + NO3-(aq) + Mg(OH)2(s)

and by removing the spectator ions, the (AP Exam format) net ionic equation is:

Mg2+ + 2 OH- → Mg(OH)2

Beginning with the May, 2007 AP exam (Question 4), all reactions must be written in balanced, net ionic form.

Topic 4 – Acid-Base Reactions

Acids are substances that dissociate in water to produce H+ ions. Bases are substances that dissociate in water to produce OH- ions. Strong acids and bases dissociate completely. Weak acids and bases are soluble in their molecular form and only dissociate to a small extent. You must memorize the common strong acids and bases:

Acids Bases

HCl hydrochloric NaOH sodium hydroxide

HBr hydrobromic and all other group I hydroxides

HI hydroiodic Ca(OH)2 calcium hydroxide

HClO3 chloric Sr(OH)2 strontium hydroxide

HClO4 perchloric Ba(OH)2 barium hydroxide

HNO3 nitric (the “heavy” group II metal hydroxides)

H2SO4 sulfuric

You must also memorize several of the more common weak acids and bases:

HCH3COO acetic acid or ethanoic acid

H3PO4 phosphoric acid

H2SO3 sulfurous acid

HCHOO formic acid or methanoic acid

NH3 ammonia (a weak base)

Acids and bases react with each other in neutralization reactions to form water and a salt. For example:

molecular equation net ionic equation

Acids and bases react with each other in neutralization reactions to form water and a salt:

H2SO4 + 2NaOH → 2H2O + Na2SO4 2H+ + OH- → H2O

Mg(OH)2 + 2HCl → MgCl2 + 2H2O Mg(OH)2 + 2H+ → Mg2+ + 2H2O (HCl is strong!)

Acids and bases react with each other in neutralization reactions to form a gas:

2HCl + Na2S → H2S + 2NaCl 2H+ S2- → H2S (formation of a gas, H2S)

HCl + NaHCO3 → NaCl + H2O + CO2 H+ + HCO3- → H2O + CO2

Recognize these reactions when you see them and be able to write net ionic equations.

Topic 5 – Oxidation-Reduction (Redox) Reactions

Redox reactions occur through the transfer of electrons between reactants. A species is said to be oxidized when it loses electrons. A species is said to be reduced when it gains electrons. Use this mnemonic device:

OIL RIG

Reduction Is Gaining

Oxidation Is Losing

Oxidation Numbers:

The assignment of oxidation numbers to atoms within a compound or ion is a useful bookkeeping exercise. Think of an oxidation number as the charge on an atom or, if it is not an ion, the “pretend” charge on an atom in a covalent bond. For example, in water, H2O, the bonds are covalent, so there is no actual charge on hydrogen or oxygen. However, we know that oxygen is highly electronegative and the electrons are held more closely to the oxygen than the hydrogen atoms. Thus, we can “pretend” that the oxygen has a charge (oxidation number) of 2- and each of the hydrogens has a charge (oxidation number) of 1+. Note that the oxidation numbers add up to the charge on the water molecule, which is zero [ (+1) + (+1) + (-2) = (0) ].

You must be able to use the following rules to determine oxidation numbers:

1.  The oxidation number of elements in their elemental form is 0.

2.  The oxidation number on any monatomic ion is the charge.

3.  The oxidation number of fluorine is always -1

4.  The oxidation number of hydrogen is always +1, except it is -1 when bonded to a metal.

5.  The oxidation number of oxygen is usually -2, except when it is part of the peroxide ion, O22- when it is -1.

6.  The oxidation of other atoms is usually same as the charge if it was a common ion.

Example 6:  Determine the oxidation number on each atom of SBr2.

atom count oxidation # total rule

S: 1 +2 +2 rule #7 – add to zero

Br: 2 -1 -2 rule #6 – Br is -1 if ion

0

Example 7:  Determine the oxidation number on each atom of Cr2O72-.

Cr 2 +6 +12 rule 7 – add to -2

O 7 -2 -14 rule 5 – oxygen is -2

-2 the charge on Cr2O72- is 2-

Agents and half-reactions:

You also need to be able to identify the atoms that are oxidized, the atoms that are reduced, the agent that oxidizes the oxidized atom (oxidizing agent), and the agent that reduces the reduced atom (reducing agent).

Example 8:  Name the element oxidized, the element reduced, the oxidizing agent, and the reducing agent in the following reaction: 2Al + Fe2O3 → Al2O3 + 2Fe

According to rule 1, the oxidation numbers of elemental Al and Fe are 0. Using the rules as in examples 6 and 7 above, we determine that the oxidation number of oxygen in both compounds is –2, the oxidation number of Fe in Fe2O3 is +3, and the oxidation number of Al in Al2O3 is also +3. Thus,

Aluminum is oxidized from 0 to +3 (oxidation is losing electrons)

Iron is reduced from +3 to 0 (reduction is gaining electrons)

Fe2O3 is the agent that caused Al to be oxidized (Fe2O3 is oxidizing agent)

Elemental Al is the agent that caused Fe in Fe2O3 to be reduced (Al is reducing agent)

Finally, you must be able to write the oxidation and reduction half-reactions.

Example 9:  Write the oxidation and reduction half-reactions for Example 8 above.

Oxidation: Al → Al3+ + 3e-

Reduction: Fe3+ + 3e- → Fe

Note that adding the half reactions gives the net reaction:

Al + Fe3+ = Al3+ + Fe

Activity series:

The activity series is just a summary of many experimental replacement reactions, and can be used to predict when hydrogen and metal displacement reactions will occur. Given the activity series, tha following two rules apply:

1.  Hydrogen displacement: Any metal above hydrogen in the activity series will displace hydrogen from water or from an acid. Metals below hydrogen will not react with either water or an acid.

2.  Metal displacement: Any metal will react with a compound containing any metal ion listed below it.

Example 10:  Predict the outcome of the reactions shown below and state the rule that pertains:

Mg(s) + HCl(aq) → ?

Mg(s) + 2HCl(aq) → MgCl2(aq) + H2(g)

(magnesium lies above hydrogen in the series, so the hy-

drogen in HCl is displaced.)

Al(s) + Cu(NO3)2 → ?

2Al(s) + 3Cu(NO3)2(aq) → 3Cu(s) + 2Al(NO3)3(aq)

(aluminum is above copper in the series or more reactive,

so the aluminum displaces the copper.)

You don’t need to memorize the activity series, because the order is the same as the Standard Reduction Potentials table that is given in the free response section of the AP exam. However you should understand the trend of activity as it relates to the periodic table, since you may need to make some predictions in the multiple-choice section where you only have access to the periodic table. For example, know that aluminum is much more active than copper and magnesium is much more active than lead. Remember, reactivity of the alkali metals is highest and general goes to a minimum at gold, and then rises again to the right of gold.

Topic 6 – Solution Stoichiometry

Problems in solution stoichiometry require you to read carefully, work methodically, and be flexible in your problem-solving strategies.

Gravimetric analysis:

Gravimetric analysis is an analytical technique based on separating solids from a solution or mixture. Generally, in involves forming a precipitate, measuring its mass, and then using stoichiometry to make calculations regarding the original solute or solution. It requires precipitation reactions to proceed to completion (no slightly soluble precipitates).

Example 11:  137.5 mL of a solution containing lead ions is mixed with 1.0 M NaCl until no more precipitate forms. The precipitate is filtered, washed, and dried, and then found to have a mass of .7038 g.

1. What mass of lead was in the original sample?

1. What was the concentration of lead the original sample?

a. the equation for the precipitation reaction must be: Pb2+ + 2Cl- → PbCl2

b. M = n/V =

Acid-base titration:

Titration calculations are stoichiometry problems disguised with units of molarity instead of the usual units of grams and moles. Always remember to convert between species using mole ratios from the balanced equation rather than molarity or mass.

Example 12:  What is the concentration of a hydrochloric acid solution if 39.72 mL of 0.1015 M NaOH is required to neutralize a 50.00 mL sample of the unknown acid solution?

The balanced equation is: H+ + OH- → H2O

= .08063M

Note that this entire equation is actually a manifestation of M1V1 = M2V2 or (if a=acid

and b= base): MaVa = MbVb. Like this:

Ma = ?

Va = 50.00 mL

Mb = 0.1015 M

Vb = 39.72 mL

Caution!!! This only works if the acid-base mole ratio is 1:1