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IONIC COMPOUNDS Chapter 5

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Chapter 5 Many reactions involve ionic compounds, especially reactions in water aqueous solutions. K+(aq) + MnO4-(aq) KMnO4 in water An Ionic Compound, CuCl2, in ... – PowerPoint PPT presentation

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Title: IONIC COMPOUNDS Chapter 5


1
IONIC COMPOUNDSChapter 5
  • Many reactions involve ionic compounds,
    especially reactions in water aqueous solutions.

KMnO4 in water
2
An Ionic Compound, CuCl2, in Water
3
Aqueous Solutions
  • How do we know ions are present in aqueous
    solutions?
  • The solutions conduct electricity!
  • They are called ELECTROLYTES
  • HCl, MgCl2, and NaCl are strong electrolytes.
    They dissociate completely (or nearly so) into
    ions.

4
Aqueous Solutions
  • HCl, MgCl2, and NaCl are strong electrolytes.
    They dissociate completely (or nearly so) into
    ions.

5
Aqueous Solutions
  • Acetic acid ionizes only to a small extent, so it
    is a weak electrolyte.
  • CH3CO2H(aq) ---gt CH3CO2-(aq) H(aq)

6
Aqueous Solutions
  • Acetic acid ionizes only to a small extent, so it
    is a weak electrolyte.
  • CH3CO2H(aq) ---gt CH3CO2-(aq) H(aq)

7
Aqueous Solutions
  • Some compounds dissolve in water but do not
    conduct electricity. They are called
    nonelectrolytes.

Examples include sugar ethanol ethylene glycol
8
Water Solubility of Ionic Compounds
If one ion from the Soluble Compd. list is
present in a compound, the compound is water
soluble.
Screen 5.4 Figure 5.1
Guidelines to predict the solubility of ionic
compounds
9
Water Solubility of Ionic Compounds
  • Common minerals are often formed with anions that
    lead to insolubility
  • sulfide fluoride
  • carbonate oxide

10
ACIDS
An acid -------gt H in water
  • Some strong acids are
  • HCl hydrochloric
  • H2SO4 sulfuric
  • HClO4 perchloric
  • HNO3 nitric

11
ACIDS
An acid -------gt H in water
  • HCl(aq) ---gt H(aq) Cl-(aq)

12
The Nature of Acids
13
Weak Acids
  • WEAK ACIDS weak electrolytes
  • CH3CO2H
  • acetic acid
  • H2CO3 carbonic acid
  • H3PO4 phosphoric acid
  • HF
  • hydrofluoric acid

14
ACIDS
  • Nonmetal oxides can be acids
  • CO2(aq) H2O(liq) ---gt H2CO3(aq)
  • SO3(aq) H2O(liq) ---gt H2SO4(aq)
  • and can come from burning coal and oil.

15
BASESsee Screen 5.9 and Table 5.2
Base ---gt OH- in water
  • NaOH(aq) ---gt Na(aq) OH-(aq)

NaOH is a strong base
16
Ammonia, NH3An Important Base
17
BASES
  • Metal oxides are bases
  • CaO(s) H2O(liq)
  • --gt Ca(OH)2(aq)

CaO in water. Indicator shows solution is basic.
18
Know the strong acids bases!
19
Net Ionic Equations
  • Mg(s) 2 HCl(aq) --gt H2(g) MgCl2(aq)
  • We really should write
  • Mg(s) 2 H(aq) 2 Cl-(aq) ---gt
    H2(g) Mg2(aq) 2 Cl-(aq)

The two Cl- ions are SPECTATOR IONS they do not
participate. Could have used NO3-.
20
Net Ionic Equations
  • Mg(s) 2 HCl(aq) --gt H2(g)
    MgCl2(aq)
  • Mg(s) 2 H(aq) 2 Cl-(aq) ---gt H2(g)
    Mg2(aq) 2 Cl-(aq)

We leave the spectator ions out Mg(s) 2
H(aq) ---gt H2(g) Mg2(aq)
to give the NET IONIC EQUATION
21
Chemical Reactions in WaterSections 5.2
5.4-5.6CD-ROM Ch. 5
  • We will look at EXCHANGE REACTIONS

Pb(NO3) 2(aq) 2 KI(aq) ----gt PbI2(s) 2
KNO3 (aq)
The anions exchange places between cations.
22
Precipitation Reactions
  • The driving force is the formation of an
    insoluble compound a precipitate.
  • Pb(NO3)2(aq) 2 KI(aq) -----gt
  • 2 KNO3(aq) PbI2(s)
  • Net ionic equation
  • Pb2(aq) 2 I-(aq) ---gt PbI2(s)

23
Acid-Base Reactions
  • The driving force is the formation of water.
  • NaOH(aq) HCl(aq) ---gt
  • NaCl(aq) H2O(liq)
  • Net ionic equation
  • OH-(aq) H(aq) ---gt H2O(liq)
  • This applies to ALL reactions of STRONG acids and
    bases.

24
Acid-Base Reactions CCR, page 162
25
Acid-Base Reactions
  • 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 ---gt MX H2O
  • Mn comes from base Xn- comes from acid
  • This is one way to make ionic compounds!

26
Gas-Forming Reactions
  • This is primarily the chemistry of metal
    carbonates.
  • CO2 and water ---gt H2CO3
  • H2CO3(aq) Ca2 ---gt
  • 2 H(aq) CaCO3(s) (limestone)
  • Adding acid reverses this reaction.
  • MCO3 acid ---gt CO2 salt

27
Gas-Forming Reactions
  • CaCO3(s) H2SO4(aq) ---gt
  • 2 CaSO4(s) H2CO3(aq)
  • Carbonic acid is unstable and forms CO2 H2O
  • H2CO3(aq) ---gt CO2 (g) water
  • (Antacid tablet has citric acid NaHCO3)

28
See also Gas Forming Reactions in Biological
Systems Three of the pioneers in working out the
roles of NO forming reactions shared a Nobel
Prize in 1988 for their discoveries.
29
Quantitative Aspects of Reactions in
SolutionSections 5.8-5.10
30
Terminology
  • In solution we need to define the -
  • SOLVENT
  • the component whose physical state
    is preserved when
    solution forms
  • SOLUTE
  • the other solution component

31
Concentration of Solute
  • The amount of solute in a solution is given by
    its concentration.

Concentration (M)
32
1.0 L of water was used to make 1.0 L of
solution. Notice the water left over.
CCR, page 177
33
PROBLEM Dissolve 5.00 g of NiCl26 H2O in
enough water to make 250 mL of solution.
Calculate molarity.
Step 1 Calculate moles of NiCl26H2O
Step 2 Calculate molarity
NiCl26 H2O 0.0841 M
34
The Nature of a CuCl2 SolutionIon Concentrations
  • CuCl2(aq) --gt
  • Cu2(aq) 2 Cl-(aq)
  • If CuCl2 0.30 M, then
  • Cu2 0.30 M
  • Cl- 2 x 0.30 M

35
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

36
USING MOLARITY
What mass of oxalic acid, H2C2O4, is required to
make 250. mL of a 0.0500 M solution?
moles MV
  • Step 1 Calculate moles of acid required.
  • (0.0500 mol/L)(0.250 L) 0.0125 mol
  • Step 2 Calculate mass of acid required.
  • (0.0125 mol )(90.00 g/mol) 1.13 g

37
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.

38
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!

39
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?
40
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 ---gt

41
PROBLEM You have 50.0 mL of 3.0 M NaOH and you
want 0.50 M NaOH. What do you do?
  • Amount of NaOH in original solution
  • M V
  • (3.0 mol/L)(0.050 L) 0.15 mol NaOH
  • Amount of NaOH in final solution must also 0.15
    mol NaOH
  • 0.15/Volume of final solution 0.5 M/ 1 L
  • Volume of final solution
  • (0.15 mol NaOH)(1 L/0.50 mol) 0.30 L
  • or 300 mL

42
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.

43
Preparing Solutions by Dilution
  • A shortcut
  • Cinitial Vinitial Cfinal Vfinal

44
The pH Scale
  • pH log (1/ H)
  • - log H
  • Remember log a b if 10ba
  • In a neutral solution, H OH- 1.00
    x 10-7 M at 25 oC
  • pH - log H -log (1.00 x 10-7)
    - (-7)
  • 7
  • See CD Screen 5.17 for a tutorial

45
pH, a Concentration Scale
  • pH a way to express acidity -- the concentration
    of H in solution.

Low pH high H
High pH low H
Acidic solution pH lt 7 Neutral pH 7 Basic
solution pH gt 7
46
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 - (-2.80)
  • pH 2.80

Whats the origin of the name of the soda 7up ?
47
ACID-BASE REACTIONSTitrations
  • H2C2O4(aq) 2 NaOH(aq) ---gt
  • acid base
  • Na2C2O4(aq) 2 H2O(liq)
  • Carry out this reaction using a TITRATION.

48
Setup for titrating an acid with a base
CCR, page 186
49
Titration
  • 1. Add solution from the 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- --gt H2O
  • 5. At equivalence point
  • moles H moles OH-

50
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?

51
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 reqd
52
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
  • 0.0118 mol acid
  • Step 2 Calculate amount of NaOH reqd
  • 0.0236 mol NaOH
  • Step 3 Calculate concentration of NaOH

NaOH 0.663 M
53
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) ---gt
  • Na2C4H4O5(aq) 2 H2O(liq)
  • 76.80 g of apple requires 34.56 mL of 0.663 M
    NaOH for titration. What is weight of malic
    acid?

54
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.
  • C V (0.663 M)(0.03456 L)
  • 0.0229 mol NaOH
  • Step 2 Calculate amount of acid titrated.

0.0115 mol acid
55
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.
0.0229 mol NaOH Step 2 Calculate amount
of acid titrated 0.0115 mol acid
  • Step 3 Calculate mass of acid titrated.

56
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.
  • 0.0229 mol NaOH
  • Step 2 Calculate amount of acid titrated
  • 0.0115 mol acid
  • Step 3 Calculate mass of acid titrated.
  • 1.54 g acid

Step 4 Calculate malic acid.
57
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

58
SOLUTION STOICHIOMETRYGas-forming reactions
  • 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?

59
GENERAL PLAN FOR STOICHIOMETRY CALCULATIONS
60
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?
  • Step 1 Write the balanced equation
  • Zn(s) 2 HCl(aq) --gt ZnCl2(aq) H2(g)
  • Step 2 Calculate amount of Zn

Step 3 Use the stoichiometric factor
61
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?
  • Step 3 Use the stoichiometric factor

Step 4 Calculate volume of HCl reqd
62
EXCHANGE Precipitation Reactions
EXCHANGE Acid-Base Reactions
EXCHANGE Gas-Forming Reactions
REACTIONS
REDOX REACTIONS
63
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

64
REDOX REACTIONS
  • Cu(s) 2 Ag(aq)
  • ---gt Cu2(aq) 2 Ag(s)
  • In all reactions if something has been oxidized
    then something has also been reduced

65
Why Study Redox Reactions
Batteries
Corrosion
Manufacturing metals
Fuels
66
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

67
OXIDATION NUMBERS
  • 3. F always has an oxidation number of -1 when
    forming compounds with other elements.
  • 4. Cl, Br and I have oxidation numbers of -1 when
    forming compounds with other elements, except
    when combined with oxygen and fluorine.
  • 5a. O has ox. no. -2
  • (except in peroxides in H2O2, O -1)

68
OXIDATION NUMBERS
  • 5b. Ox. no. of H 1
  • (except when H is associated with a metal as in
    NaH where it is -1)
  • 6. Algebraic sum of oxidation numbers
  • 0 for a compound
  • overall charge for an ion

69
OXIDATION NUMBERS
  • NH3 N
  • ClO- Cl
  • H3PO4 P
  • MnO4- Mn
  • Cr2O72- Cr
  • C3H8 C

70
Recognizing a Redox Reaction
  • Corrosion of aluminum
  • 2 Al(s) 3 Cu2(aq) --gt 2 Al3(aq) 3 Cu(s)
  • Al(s) --gt 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.

71
Recognizing a Redox Reaction
  • Corrosion of aluminum
  • 2 Al(s) 3 Cu2(aq) --gt 2 Al3(aq) 3 Cu(s)
  • Cu2(aq) 2 e- --gt 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.

72
Recognizing a Redox Reaction
  • Notice that the 2 half-reactions add up to give
    the overall reaction if we use 2 moles of Al
    and 3 moles of Cu2.
  • 2 Al(s) --gt 2 Al3(aq) 6 e-
  • 3 Cu2(aq) 6 e- --gt 3 Cu(s)
  • --------------------------------------------------
    ---------
  • 2 Al(s) 3 Cu2(aq) ---gt 2 Al3(aq) 3 Cu(s)
  • Final eqn. is balanced for mass and charge.

73
Common Oxidizing and Reducing AgentsSee Table
5.4
Cu HNO3 --gt Cu2 NO2
2 K 2 H2O --gt 2 KOH H2
74
Recognizing a Redox ReactionSee 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

75
Examples of Redox Reactions
Metal halogen 2 Al 3 Br2 ---gt Al2Br6
76
Examples of Redox Reactions
Nonmetal (P) Oxygen
Metal (Mg) Oxygen
77
Examples of Redox Reactions
Metal acid Mg HCl Mg reducing agent H
oxidizing agent
Metal acid Cu HNO3 Cu reducing agent HNO3
oxidizing agent
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