Chemistry and Chemical Reactivity Chapter 5 Reactions in Aqueous Solution PDF

Summary

This textbook chapter explains reactions in aqueous solutions, focusing on ionic compounds and their behavior. It covers strong and weak electrolytes, acids, bases, and various reaction types. Formulas, examples, and illustrations are used to explain the concepts.

Full Transcript

Chemistry and Chemical Reactivity 1

6th Edition
John C. Kotz
Paul M. Treichel
Gabriela C. Weaver

CHAPTER 5
Reactions in Aqueous Solution
Lectures written by John Kotz

©2006
© 2006 Brooks/Cole
Brooks/Cole Thomson
- Thomson
 2

Reactions
in Aqueous Solution
Many reactions involve ionic compounds,
especially reactions in water — aqueous
solutions.
KMnO4 in water K+(aq) + MnO4-(aq)

© 2006 Brooks/Cole - Thomson
 3

CCR, page 177

An Ionic Compound,
CuCl2, in Water

© 2006 Brooks/Cole - Thomson
 Aqueous Solutions 4

How do we know ions are
present in aqueous
solutions?
The solutions conduct
electricity!
They are called
ELECTROLYTES
HCl, CuCl2, and NaCl are
strong electrolytes.
They dissociate
completely (or nearly so)
into ions.
© 2006 Brooks/Cole - Thomson
 Aqueous Solutions
5

HCl, CuCl2, and NaCl are strong
electrolytes. They dissociate completely
(or nearly so) into ions.

© 2006 Brooks/Cole - Thomson
 Aqueous Solutions
6

Acetic acid ionizes only to a small extent, so
it is a weak electrolyte.
CH3CO2H(aq) CH CO 3 2
-(aq) + H+(aq)

© 2006 Brooks/Cole - Thomson
 Aqueous
7

Solutions
Acetic acid ionizes only to a
small extent, so it is a
weak electrolyte.

CH3CO2H(aq) CH CO 3 2
-

(aq) + H+(aq)

© 2006 Brooks/Cole - Thomson
 Aqueous 8

Solutions
Some compounds
dissolve in water but
do not conduct
electricity. They are
called nonelectrolytes.

Examples include:
sugar
ethanol
ethylene glycol

© 2006 Brooks/Cole - Thomson
 Water Solubility of Ionic Compounds 9

If one ion from the “Soluble
Compd.” list is present in a
compound, the compound is
water soluble.

© 2006 Brooks/Cole - Thomson
 10

Water Solubility of Ionic Compounds
Common minerals are often formed with
anions that lead to insolubility:
sulfide fluoride
carbonate oxide

Iron pyrite, a sulfide
Orpiment,
arsenic sulfide
Azurite, a copper
carbonate
© 2006 Brooks/Cole - Thomson
 ACIDS
11

An acid -------> H+ in water

Some strong acids are
HCl hydrochloric
H2SO4 sulfuric
HClO4 perchloric HNO3

HNO3 nitric

© 2006 Brooks/Cole - Thomson
 ACIDS
12

An acid -------> H+ in water

HCl(aq) H+(aq) + Cl-(aq)

© 2006 Brooks/Cole - Thomson
 13

The
Nature of
Acids

HCl Cl-

H 2O H 3O+
hydronium
ion
© 2006 Brooks/Cole - Thomson
 14

Weak Acids
WEAK ACIDS = weak
electrolytes
CH3CO2H
acetic acid
H2CO3 Acetic acid
carbonic acid
H3PO4
phosphoric acid
HF
hydrofluoric acid
© 2006 Brooks/Cole - Thomson
 ACIDS
15

Nonmetal oxides can be acids
CO2(aq) + H2O(liq)
H2CO3(aq)
SO3(aq) + H2O(liq)
H2SO4(aq)
and can come from burning
coal and oil.

© 2006 Brooks/Cole - Thomson
 BASES
16

see Screen 5.9 and Table 5.2

Base ---> OH- in water

NaOH(aq) Na+(aq) + OH-(aq)

NaOH is
a strong
base

© 2006 Brooks/Cole - Thomson
 17
Ammonia, NH3
An Important Base

© 2006 Brooks/Cole - Thomson
 18

BASES
Metal oxides are
bases
CaO(s) + H2O(liq)
Ca(OH)2(aq)

CaO in water. Indicator
shows solution is basic.
© 2006 Brooks/Cole - Thomson
 19

Know the strong
acids & bases!
© 2006 Brooks/Cole - Thomson
 20

Net Ionic
Equations
Mg(s) + 2 HCl(aq) H2(g) + MgCl2(aq)
We really should write
Mg(s) + 2 H+(aq) + 2 Cl-(aq) --->
H2(g) + Mg2+(aq) + 2 Cl-(aq)

The two Cl- ions are SPECTATOR IONS —
they do not participate. Could have used NO3-.
© 2006 Brooks/Cole - Thomson
 Net Ionic Equations
21

Mg(s) + 2 HCl(aq)
H2(g) + MgCl2(aq)

Mg(s) + 2 H+(aq) + 2 Cl-(aq)
H2(g) + Mg2+(aq) + 2 Cl-(aq)

We leave the spectator ions out —
Mg(s) + 2 H+(aq) ---> H2(g) + Mg2+(aq)

to give the NET IONIC EQUATION

© 2006 Brooks/Cole - Thomson
 22
Chemical Reactions in Water
Sections 5.2 & 5.4-5.6—CD-ROM Ch. 5

We will look at Pb(NO3) 2(aq) + 2 KI(aq)
EXCHANGE ----> PbI2(s) + 2 KNO3 (aq)
REACTIONS

AX + B Y AY + B X

The anions
exchange places
between cations.

© 2006 Brooks/Cole - Thomson
 23

Precipitation Reactions
The “driving force” is the formation of an
insoluble compound — a precipitate.

Pb(NO3)2(aq) + 2 KI(aq)
2 KNO3(aq) + PbI2(s)

Net ionic equation
Pb2+(aq) + 2 I-(aq) PbI2(s)

© 2006 Brooks/Cole - Thomson
 24

Acid-Base Reactions
The “driving force” is the formation of water.
NaOH(aq) + HCl(aq)
NaCl(aq) + H2O(liq)
Net ionic equation
OH-(aq) + H+(aq)
H2O(liq)
This applies to ALL reactions
of STRONG acids and bases.

© 2006 Brooks/Cole - Thomson
 Acid-Base Reactions 25
CCR, page 191

© 2006 Brooks/Cole - Thomson
 Acid-Base Reactions
26

A-B reactions are sometimes called
NEUTRALIZATIONS because the solution is
neither acidic nor basic at the end.

The other product of the A-B reaction is a SALT, MX.

HX + MOH MX + H2O
Mn+ comes from base & Xn- comes from acid
This is one way to make compounds!

© 2006 Brooks/Cole - Thomson
 27

Gas-Forming Reactions
This is primarily the chemistry of metal carbonates.

CO2 and water H2CO3

H2CO3(aq) + Ca2+
2 H+(aq) + CaCO3(s) (limestone)
Adding acid reverses this reaction.

MCO3 + acid CO2 + salt

© 2006 Brooks/Cole - Thomson
 28

Gas-Forming
Reactions

CaCO3(s) + H2SO4(aq)
2 CaSO4(s) + H2CO3(aq)
Carbonic acid is unstable and forms CO2 & H2O
H2CO3(aq) CO2 + water
(Antacid tablet has citric acid + NaHCO3)

© 2006 Brooks/Cole - Thomson
 29

© 2006 Brooks/Cole - Thomson
 30

Quantitative Aspects
of
Reactions in Solution
Sections 5.8-5.10

© 2006 Brooks/Cole - Thomson
 Terminology
31

In solution we need to define the
SOLVENT
the component whose
physical state is
preserved when
solution forms
SOLUTE
the other solution component

© 2006 Brooks/Cole - Thomson
 32

Concentration of Solute

The amount of solute in a solution
is given by its concentration.

moles solute
Molarity(M) =
liters of solution

Concentration (M) = [ …]

© 2006 Brooks/Cole - Thomson
 33

1.0 L of water
was used to
make 1.0 L of
solution. Notice
the water left
over.

CCR, page 206

© 2006 Brooks/Cole - Thomson
 34

Preparing a Solution

Active Figure 5.18

© 2006 Brooks/Cole - Thomson
 35

PROBLEM: Dissolve 5.00 g of NiCl2 6 H2O
in enough water to make 250 mL of solution.
Calculate molarity.

© 2006 Brooks/Cole - Thomson
 The Nature of a CuCl2 Solution:
36

Ion Concentrations

CuCl2(aq)

Cu2+(aq) + 2 Cl-(aq)

If [CuCl2] = 0.30 M, then

[Cu2+] = 0.30 M
[Cl-] = 2 x 0.30 M

© 2006 Brooks/Cole - Thomson
 37

USING MOLARITY
What mass of oxalic acid, H2C2O4, is
required to make 250. mL of a
0.0500 M solution?
Because
Conc (M) = moles/volume = mol/V
this means that

moles = M V

© 2006 Brooks/Cole - Thomson
 USING MOLARITY
38

What mass of oxalic acid, H2C2O4, is
required to make 250. mL of a 0.0500 M
solution?
moles = M V

© 2006 Brooks/Cole - Thomson
 39

Preparing Solutions
Weigh out a solid
solute and dissolve in a
given quantity of
solvent.
Dilute a concentrated
solution to give one
that is less
concentrated.

© 2006 Brooks/Cole - Thomson
 40

Preparing a Solution by
Dilution

© 2006 Brooks/Cole - Thomson
 41
PROBLEM: You have 50.0 mL of 3.0 M
NaOH and you want 0.50 M NaOH.
What do you do?

Add water to the 3.0 M solution to lower
its concentration to 0.50 M
Dilute the solution!

© 2006 Brooks/Cole - Thomson
 42
PROBLEM: You have 50.0 mL of 3.0 M
NaOH and you want 0.50 M NaOH. What do
you do?

But how much water
do we add?

© 2006 Brooks/Cole - Thomson
 43
PROBLEM: You have 50.0 mL of 3.0 M
NaOH and you want 0.50 M NaOH. What do
you do?

How much water is added?

The important point is that

moles of NaOH in ORIGINAL solution =
moles of NaOH in FINAL solution

© 2006 Brooks/Cole - Thomson
 44
PROBLEM: You have 50.0 mL of 3.0 M NaOH and
you want 0.50 M NaOH. What do you do?

© 2006 Brooks/Cole - Thomson
 45
PROBLEM: You have 50.0 mL of 3.0 M
NaOH and you want 0.50 M NaOH. What do
you do?

Conclusion:
add 250 mL
of water to
50.0 mL of
3.0 M NaOH
to make 300
mL of 0.50 M
NaOH.

© 2006 Brooks/Cole - Thomson
 46

Preparing Solutions by
Dilution

A shortcut

Cinitial Vinitial = Cfinal Vfinal

© 2006 Brooks/Cole - Thomson
 47

SOLUTION STOICHIOMETRY
Section 5.10

Zinc reacts with
acids to produce H2
gas.
Have 10.0 g of Zn
What volume of
2.50 M HCl is
needed to convert
the Zn completely?

© 2006 Brooks/Cole - Thomson
 GENERAL PLAN FOR STOICHIOMETRY 48

CALCULATIONS

Mass Mass
zinc HCl

Stoichiometric
Moles factor Moles
zinc HCl

Volume
HCl
© 2006 Brooks/Cole - Thomson
 49
Zinc reacts with acids to produce H2 gas. If you
have 10.0 g of Zn, what volume of 2.50 M HCl is
needed to convert the Zn completely?

© 2006 Brooks/Cole - Thomson
 pH, a Concentration Scale
50

pH: a way to express acidity -- the concentration of
H+ in solution.

Low pH: high [H+] High pH: low [H+]
Acidic solution pH < 7
Neutral pH = 7
Basic solution pH > 7
© 2006 Brooks/Cole - Thomson
 51
The pH Scale
pH = log (1/ [H+])
= - log [H+]
In a neutral solution,
[H+] = [OH-] = 1.00 x 10-7 M at 25 oC
pH = - log [H+] = -log (1.00 x 10-7) =
- [0 + (-7)]
= 7
See CD Screen 5.17 for a tutorial
See book Appendix A.3 for more on logs

© 2006 Brooks/Cole - Thomson
 52
[H+] and pH
If the [H+] of soda is 1.6 x 10-3 M,
the pH is ____?
Because pH = - log [H+]
then
pH= - log (1.6 x 10-3)
pH = -{log (1.6) + log (10-3)}
pH = -{0.20 - 3.00)

pH = 2.80

© 2006 Brooks/Cole - Thomson
 53
pH and [H+]
If the pH of Coke is 3.12, it is ____________.
Because pH = - log [H+] then
log [H+] = - pH
Take antilog and get

[H+] = 10-pH
[H+] = 10-3.12 =
7.6 x 10-4 M

© 2006 Brooks/Cole - Thomson
 54

ACID-BASE REACTIONS
Titrations
H2C2O4(aq) + 2 NaOH(aq)
acid base
Na2C2O4(aq) + 2 H2O(liq)
Carry out this reaction using a TITRATION.

Oxalic acid,
H2C2O4

© 2006 Brooks/Cole - Thomson
 Setup for titrating an acid with a base 55

Active Figure 5.23
© 2006 Brooks/Cole - Thomson
 56
1. Add solution from the
Titration buret.
2. Reagent (base) reacts
with compound (acid) in
solution in the flask.
3. Indicator shows when
exact stoichiometric
reaction has occurred.
4. Net ionic equation
H+ + OH- H2O
5. At equivalence point
moles H+ = moles OH-

© 2006 Brooks/Cole - Thomson
 57
LAB PROBLEM #1: Standardize a
solution of NaOH — i.e., accurately
determine its concentration.

1.065 g of H2C2O4 (oxalic acid) requires
35.62 mL of NaOH for titration to an
equivalence point. What is the
concentration of the NaOH?

© 2006 Brooks/Cole - Thomson
 58

1.065 g of H2C2O4 (oxalic acid) requires 35.62
mL of NaOH for titration to an equivalence
point. What is the concentration of the NaOH?

Step 1: Calculate amount of H2C2O4

Step 2: Calculate amount of NaOH req’d

Step 3: Calculate concentration of NaOH

© 2006 Brooks/Cole - Thomson
 59

LAB PROBLEM #2:
Use standardized NaOH to determine
the amount of an acid in an unknown.

Apples contain malic acid, C4H6O5.

C4H6O5(aq) + 2 NaOH(aq)
Na2C4H4O5(aq) + 2 H2O(liq)
76.80 g of apple requires 34.56 mL of the
standardized NaOH for titration. What is
weight % of malic acid?

© 2006 Brooks/Cole - Thomson
 60
76.80 g of apple requires 34.56 mL of
0.663 M NaOH for titration. What is
weight % of malic acid?

Step 1: Calculate amount of NaOH used.
Step 2: Calculate amount of acid titrated.
Step 3: Calculate mass of acid titrated.
Step 4: Calculate % malic acid.

© 2006 Brooks/Cole - Thomson
 61

Oxidation-Reduction Reactions
Section 5.7

Thermite reaction
Fe2O3(s) + 2 Al(s)

2 Fe(s) + Al2O3(s)

© 2006 Brooks/Cole - Thomson
 62
EXCHANGE: Precipitation Reactions

EXCHANGE EXCHANGE
Gas-Forming REACTIONS Acid-Base
Reactions Reactions

REDOX
REACTIONS
© 2006 Brooks/Cole - Thomson
 63

REDOX REACTIONS
REDOX = reduction & oxidation
2 H2(g) + O2(g) 2 H2O(liq)

© 2006 Brooks/Cole - Thomson
 64

REDOX REACTIONS
REDOX = reduction & oxidation
Corrosion of aluminum

2 Al(s) + 3 Cu2+(aq) 2 Al3+(aq) + 3 Cu(s)

© 2006 Brooks/Cole - Thomson
 65

REDOX REACTIONS

Cu(s) + 2 Ag+(aq) Cu2+(aq) + 2 Ag(s)

In all reactions if
something has been
oxidized then
something has also
been reduced

© 2006 Brooks/Cole - Thomson
 66

REDOX REACTIONS
Cu(s) + 2 Ag+(aq) Cu2+(aq) + 2 Ag(s)

© 2006 Brooks/Cole - Thomson
 67

Why Study Redox Reactions
Batteries

Corrosion

Manufacturing metals Fuels

© 2006 Brooks/Cole - Thomson
 68

REDOX REACTIONS
Redox reactions are characterized by
ELECTRON TRANSFER between an
electron donor and electron acceptor.
Transfer leads to—
1. increase in oxidation number
of some element = OXIDATION
2. decrease in oxidation number
of some element = REDUCTION

© 2006 Brooks/Cole - Thomson
 69
OXIDATION NUMBERS

The electric charge an element
APPEARS to have when electrons are
counted by some arbitrary rules:

1. Each atom in free element has ox. no. = 0.
Zn O2 I2 S8

2. In simple ions, ox. no. = charge on ion.
-1 for Cl- +2 for Mg2+

© 2006 Brooks/Cole - Thomson
 70
OXIDATION NUMBERS
3. O has ox. no. = -2
(except in peroxides: in H2O2, O = -1)

4. Ox. no. of H = +1
(except when H is associated with a metal as in
NaH where it is -1)
5. Algebraic sum of oxidation numbers
= 0 for a compound
= overall charge for an ion

© 2006 Brooks/Cole - Thomson
 71

OXIDATION NUMBERS
NH3 N =
Oxidation
ClO- Cl = number of F
in HF?
H3PO4 P =
MnO4- Mn =
Cr2O72- Cr =
C3H8 C =

© 2006 Brooks/Cole - Thomson
 72

Recognizing a Redox Reaction
Corrosion of aluminum

2 Al(s) + 3 Cu2+(aq) 2 Al3+(aq) + 3 Cu(s)
Al(s) Al3+(aq) + 3 e-
Ox. no. of Al increases as e- are donated by the metal.
Therefore, Al is OXIDIZED
Al is the REDUCING AGENT in this balanced half-
reaction.

© 2006 Brooks/Cole - Thomson
 73

Recognizing a Redox Reaction
Corrosion of aluminum

2 Al(s) + 3 Cu2+(aq) 2 Al3+(aq) + 3 Cu(s)
Cu2+(aq) + 2 e- Cu(s)
Ox. no. of Cu decreases as e- are accepted by the ion.
Therefore, Cu is REDUCED
Cu is the OXIDIZING AGENT in this balanced half-
reaction.

© 2006 Brooks/Cole - Thomson
 Recognizing a Redox Reaction
74

Notice that the 2 half-reactions add up to
give the overall reaction
—if we use 2 mol of Al and 3 mol of Cu2+.
2 Al(s) 2 Al3+(aq) + 6 e-
3 Cu2+(aq) + 6 e- 3 Cu(s)
-----------------------------------------------------------
2 Al(s) + 3 Cu2+(aq) 2 Al3+(aq) + 3 Cu(s)
Final eqn. is balanced for mass and charge.

© 2006 Brooks/Cole - Thomson
 75

Examples of Redox Reactions

Metal + halogen
2 Al + 3 Br2 ---> Al2Br6

© 2006 Brooks/Cole - Thomson
 76

Examples of Redox Reactions

Nonmetal (P) + Oxygen
P4O10

Metal (Mg) + Oxygen
MgO
© 2006 Brooks/Cole - Thomson
 77

Recognizing a Redox
Reaction
See Table 5.4

Reaction Type Oxidation Reduction
In terms of oxygen gain loss
In terms of halogen gain loss
In terms of electrons loss gain

© 2006 Brooks/Cole - Thomson
 Common Oxidizing and
78

Reducing Agents
See Table 5.4

Metals
(Cu) are Metals
reducing (Na, K,
agents Mg, Fe)
HNO3 is an are
oxidizing reducing
agent agents
Cu + HNO3 --> 2 K + 2 H2O -->
Cu2+ + NO2 2 KOH + H2

© 2006 Brooks/Cole - Thomson
 79

Examples of Redox Reactions
Metal + acid
Mg + HCl
Mg = reducing agent
H+ = oxidizing agent

Metal + acid
Cu + HNO3
Cu = reducing agent
HNO3 = oxidizing agent
© 2006 Brooks/Cole - Thomson