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Ch 5. Reactions of Ions and Molecules in Aqueous Solutions

Brady & Senese 5th Ed.

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Link to Sections

4.1. Special terminology applies to solutions4.2. Ionic compounds conduct electricity when dissolved in water4.3. Acids and bases are classes of compounds with special properties4.4. Naming acids and bases follows a system4.5. Ionic reactions can often be predicted4.6. The composition of a solution is described by its concentration4.7. Molarity is used for problems in solution stoichiometry4.8. Chemical analysis and titration are applications of solution stoichiometry

4.1. Special terminology applies to solutions 3

Solutions

• solution –a homogeneous mixture in which the two or more components mix freely

• solvent - the component present in the largest amount

• solute – the substance dissolved in the solvent. The solution is named by the solute.

• concentration - a solute-to-solvent or solute-to-solution ratio describing the composition of the mixture

4.1. Special terminology applies to solutions 4

The dilute solution on the left has less solute per unit volume than the (more) concentrated solution on the right

Relative concentration terms

4.1. Special terminology applies to solutions 5

• saturated –no more solute can be dissolved at the current temperature in the given amount of solvent

• solubility - the amount of solute that can dissolve in the specified amount of solvent at a given temperature (usually g solute/ 100 g solvent or moles solute/L solution)

• unsaturated - contains less solute than the solubility allows

• supersaturated- contains more solute than solubility predicts

Solubility

4.1. Special terminology applies to solutions 6

• Most solid solutes are more soluble at higher temperatures.

• Careful cooling of saturated solutions may result in a supersaturated solution

• often form a precipitate (ppt.)

Supersaturated solutions are unstable

4.2 Ionic Compounds Conduct Electricity When Dissolved in Water 7

Ionic compounds in water

• Water molecules arrange themselves around the ions and dissociate them from the lattice.

• The separated ions are “hydrated” and conduct electrical current (act as electrolytes)

• Polyatomic ions remain intact in the dissociation process.

4.2. Ionic compounds conduct electricity when dissolved in water 8

Molecular compounds in water

• The solute particles are surrounded by the water, but the molecules are not dissociated

4.2. Ionic compounds conduct electricity when dissolved in water 9

Electrical conductivity

• Strong electrolyte – aqueous solution that conducts electricity because solute is 100% dissociated into ions

• Weak electrolyte –aqueous solution that weakly conducts electricity due to low ionization

• Non-electrolyte – an aqueous solution that doesn’t conduct electricity because solute does not dissociate into ions

4.2. Ionic compounds conduct electricity when dissolved in water 10

Ionic equations show dissociated ions

• hydrated ions, with the symbol (aq), are written separately

• Na2SO4(s) → 2Na+(aq) + SO4

2-(aq)

• you might encounter the equation as:

• Na2SO4(s) → 2Na+ + SO42-

Accepted because only 2 states allow for dissociated ions (plasma and aqueous). Aqueous is far more common

It is vague and not preferred

4.2. Ionic compounds conduct electricity when dissolved in water 11

Learning check

Write the equations that illustrate the dissociation of the following:

• Na3PO4(aq)→

• Al2(SO4)3(aq) →

• CaCl2(aq) →

• Ca(MnO4)2(aq) →

2Al3+(aq) + 3SO4

2-(aq)

3Na+(aq) + PO4

3-(aq)

Ca2+(aq) + 2Cl-

(aq)

Ca2+(aq) + 2MnO4

-(aq)

4.2. Ionic compounds conduct electricity when dissolved in water 12

Your turn!

How many ions form on the dissociation of Na3PO4?

a) 1

b) 2

c) 3

d) 4

e) none of the above

4.2. Ionic compounds conduct electricity when dissolved in water 13

Writing chemical equations

• Molecular equation: Balanced, shows states, all substances electrically neutral AgNO3(aq) + KCl(aq) →AgCl(s) + KNO3(aq)

• Ionic equation: Balanced, shows states, shows strong electrolytes as

dissociated ions, net charges balance Ag+

(aq) + NO3-(aq) + K+

(aq) + Cl-(aq) →AgCl(s) + K+

(aq) + NO3-(aq)

• Net ionic equation: Balanced, shows states, eliminates spectator ions from the

ionic equation, net charges balance Ag+

(aq) + Cl-(aq) →AgCl(s)

4.2. Ionic compounds conduct electricity when dissolved in water 14

Learning check:

• Write the ionic equations for each:

• BaCl2(aq) + Pb(NO3)2(aq)→PbCl2(s) + Ba(NO3)2(aq)

• Ba2+(aq) + 2Cl-

(aq) + Pb2+(aq) + 2NO3

-(aq) →PbCl2(s) +

Ba2+(aq) + 2NO3

-(aq)

• Na2CO3(aq) +CaCl2(aq) →CaCO3(s) +2NaCl(aq)

• 2Na+(aq) + 2CO3

2-(aq) + Ca2+

(aq) + 2Cl-(aq) → CaCO3(s) +

2Na+(aq) + 2Cl-

(aq)

4.2. Ionic compounds conduct electricity when dissolved in water 15

Writing net ionic equations

• Show only those ions that were changed by the process

• Omits spectator ions: When we compare the reactant to product spectator

ions are those ions that are not changed in any way

4.2. Ionic compounds conduct electricity when dissolved in water 16

Learning check:

• Write the following as net ionic equations:

• Pb2+(aq) + 2NO3

-(aq) + 2K+

(aq) + 2I-(aq) →PbI2(s) + 2K+

(aq) + 2NO3-(aq)

• Ba2+(aq)+ 2Cl-

(aq) + 2Na+(aq) + SO4

2-(aq) → BaSO4(s) + 2Na+

(aq) )+ 2Cl-(aq)

• 2Na+(aq) )+ 2Cl-

(aq) + Hg22+

(aq) + 2NO3-(aq) → 2Na+

(aq) + 2NO3-(aq) +

Hg2Cl2(s)

2Cl-(aq) + Hg2

2+(aq) → Hg2Cl2(s)

Ba2+(aq)+ SO4

2-(aq) → BaSO4(s)

Pb2+(aq) + 2I-

(aq) → PbI2(s)

4.3.Acids and bases are classes of compounds with special properties 17

• An acid is a substance that ionizes in a reaction with water to form the hydronium ion, H3O+

• Strong acids are 100% ionized when dissolved, whereas weak acids are far less efficiently ionized

The Arrhenius definition of acids

(weak)OHCOHOH OHHC

(strong)Cl OH OH HCl

(aq)-

232)(3 (l)22(aq)32

)(-

)(3(l)2)(

aq

aqaqg

4.3.Acids and bases are classes of compounds with special properties 18

• It is common to encounter the hydrogen ion (H+) instead of the hydronium ion

• The previous ionization is, for simplicity, also written as:

H+ does not ever exist in aqueous solution- it is always attached to a water molecule as the hydronium ion

(aq)-

(aq)OH

(g) Cl H HCl 2

What is H(aq)+?

4.3.Acids and bases are classes of compounds with special properties 19

Nonmetal oxides can be acids

• Nonmetal oxides, or “acidic anhydrides” react with water to form acid solutions

• SO2(g) + H2O(l) →H2SO3(aq)

• CO2(g) + H2O(l) →H2CO3(aq)

4.3.Acids and bases are classes of compounds with special properties 20

Arrhenius bases

• Base- substance that produces hydroxide ions in water

• Molecular bases undergo an ionization (hydrolysis) reaction to form the hydroxide ions, and are weak bases

• Many N-compounds are molecular bases B(aq) + H2O(l) HB+

(aq) + OH-(aq)

4.3.Acids and bases are classes of compounds with special properties 21

Metal oxides and hydroxides are bases

• Metal hydroxide solutions dissociate into metal and hydroxide ions and are strong bases.

• NaOH(s)→Na+(aq) + OH-

(aq)

• Soluble metal oxides “basic anhydrides” react with water to form metal hydroxides that are strong bases

• CaO(s) +H2O(l) → Ca2+(aq) + 2OH-

(aq)

4.3.Acids and bases are classes of compounds with special properties 22

Strong vs. weak

• Some acids ionize 100% in water, and are termed “strong acids” and are also “strong electrolytes” HCl, HClO4, HNO3, HBr, HI, H2SO4

• The very soluble metal hydroxides are strong electrolytes and “strong bases”. Group IA hydroxides/oxides and Ca, Ba, and Sr

hydroxides/oxides.

4.3.Acids and bases are classes of compounds with special properties 23

Weak acids and bases are weak electrolytes

4.4. Naming acids and bases follows a system 24

Naming binary acids (aqueous)• prefix hydro- + nonmetal stem + the suffix –ic, followed

by the word acid • Stem is first syllable of element name. i.e. Chlorine• P and S stems use 2 syllables phosphorus, sulfur• the name of the (aq) form differs from other states due to

the ionization that occurs in water

Molecular compound Aqueous Binary Acid

HCl(g) hydrogen chloride HCl(aq) hydrochloric acid

H2S(g) hydrogen sulfide H2S(aq) hydrosulfuric acid

4.4. Naming acids and bases follows a system 25

Oxoacids (aqueous)

• named according to the anion suffix anion ends in -ite, the acid name is -ous acid ends in -ate, the acid name is -ic acid

-ate anion acids -ite anion acids

HNO3(aq) nitric acid HClO2(aq) chlorous acid

H2SO4(aq) sulfuric acid H2PO3(aq) phosphorous acid

4.3.Acids and bases are classes of compounds with special properties 26

Your turn!

Which of the following is the correct name for H2SO3(aq)?

• sulfuric acid• sulfurous acid• hydrosulfuric acid• none of the above

4.5. Ionic reactions can often be predicted 27

A reaction will exist if…

• A precipitate (insoluble product) forms from soluble reactants

• An acid reacts with a base• A weak electrolyte product is formed from strong

electrolyte reactants• A gas is formed from a mixture of reactions

4.5. Ionic reactions can often be predicted 28

Metathesis (double replacement) reactions

• AB + CD → AD + CB• Cations change partners • Charges on each ion don’t change• Formulas of the products are determined by the

charges of the reactant ions• Metathesis reactions occur only if they form a

weak electrolyte or non-electrolyte as a product (otherwise, all ions are spectator ions)

4.5. Ionic reactions can often be predicted 29

Predicting metathesis reactions• Identify the ions involved:

Do not confuse counting subscripts (those present only to make charges cancel) with those that are characteristic of a polyatomic ion

• Swap partners and make neutral with appropriate subscripts

• Assign states using solubility rules• Balance the equation

HCl(aq) + Ca(OH)2(aq) →

ions: H+, Cl-Ca2+ , OH-

counting subscript

CaCl2 + H2O(aq) (l)22

4.5. Ionic reactions can often be predicted 30

Solubility rules: soluble compounds

A general idea as to whether a fair amount of solid will dissolve is achieved using solubility rules

1. All compounds of the alkali metals (Group IA)

2. All salts containing NH4+, NO3

−, ClO4−, ClO3

−, and C2H3O2

−

3. All chlorides, bromides, and iodides (salts containing Cl−, Br−, or I−) except when combined with Ag+, Pb2+, and Hg2

2+

4. All sulfates (salts containing SO42−) except those of

Pb2+, Ca2+, Sr2+, Hg22+, and Ba2+

4.5. Ionic reactions can often be predicted 31

Solubility rules: insoluble compounds

5.  All metal hydroxides (ionic compounds containing OH−) and all metal oxides (ionic compounds containing O2−) are insoluble except those of Group IA and of Ca2+, Sr2+, and Ba2+

When metal oxides dissolve, they react with water to form hydroxides. The oxide ion, O2−, does not exist in water. For example, Na2O(s) +H2O(l)

→ 2NaOH(aq)

6. All salts that contain PO43−, CO3

2−, SO32−, and S2− are

insoluble, except those of Group IA and NH4+.

4.5. Ionic reactions can often be predicted 32

Learning check:

Which of the following compounds are expected to be soluble in water?

Ca(C2H3O2)2

FeCO3

AgCl

Yes

No

No

4.5. Ionic reactions can often be predicted 33

Learning Check:

• Pb(NO3)2(aq) + Ca(OH)2(aq) →

• BaCl2(aq) + Na2CO3(aq) →

• Na3PO4(aq) + Hg2(NO3)2(aq) →

• NaCl(aq) + Ca(NO3)2(aq) →

Pb(OH)2(s) + Ca(NO3)2(aq)

BaCO3(s) + NaCl(aq)

NaNO3(aq) + (Hg2)3(PO4) 2(s)

NR (No reaction)

Predict the products of the following:

4.5. Ionic reactions can often be predicted 34

Your turn!

Which of the following will be the solid product of the reaction of Ca(NO3)2(aq) + Na2CO3(aq) →?

a) CaCO3

b) NaNO3

c) Na(NO3)2

d) Na2(NO3)2

e) None of the above

4.5. Ionic reactions can often be predicted 35

Predicting acid-base reactions

• Neutralization: metathesis reaction in which acid + metal hydroxide or metal oxide forms water and salt NaOH(aq) + HCl(aq) →H2O(l) + NaCl(aq)

• Acid-base reaction: reaction of weak base and acid transferring a H+ ion, driven by the formation of a weaker acid. HCl(aq) + NH3(aq) →NH4Cl(aq)

4.5. Ionic reactions can often be predicted 36

Learning check

Determine the molecular, total ionic and net ionic equations

• Molecular Equation

• Total Ionic Equation (TIE)

• Net Ionic Equation (NIE)

2HCl(aq) + Ca(OH)2(aq) → 2H2O(l) + CaCl2(aq)

H+(aq) + OH-

(aq) → H2O(l)

2H+(aq)+2Cl-

(aq)+ Ca2+

(aq) +2OH-

(aq) 2H2O(l)→ + Ca 2+

(aq)+ 2Cl-(aq)

4.5. Ionic reactions can often be predicted 37

Your turn!

Which of the following is not a product of the reaction: NH3(aq) +HCN(aq) →?

a) NH3CN(aq)

b) NH4+

(aq)

c) CN-(aq)

d) None of the above

4.5. Ionic reactions can often be predicted 38

Your turn!

Which is the net ionic equation for the reaction:

NaOH(aq) + HF(aq)→?

a) Na+(aq)+ OH-

(aq) + H+(aq) + F-

(aq) →H2O(l) + NaF(aq)

b) OH-(aq) + H+

(aq) →H2O(l)

c) OH-(aq) + HF(aq) →H2O(l) + F-

(aq)

d) Na+(aq)+ OH-

(aq) + HF(aq) →H2O(l) + NaF(aq)

e) None of the above

4.6. The composition of a solution is described by its concentration 39

Molar concentrations

• In solutions, solutes are dispersed in a larger volume

• Molarity expresses the relationship between the moles of solute and the volume of the solution

• Molarity (M)=moles solute/L solution Hence, a 6.0M solution of HCl contains 6.0 mole HCl

in a liter of solution

4.6. The composition of a solution is described by its concentration 40

Learning check:

• What is the molarity of a solution created by dissolving 10.2g KNO3 in enough water to make 350 mL solution?

• What mass of KNO3 are found in 25.33 mL of .0500M KNO3 solution?

33

M KNO0500.0soln L0.02533

KNOmol?

MM KNO3 = 101.1033 g/mol

0.128 g

33 89

KNO Msoln L 0.350

KNO mol0.100

0.29 M

4.6. The composition of a solution is described by its concentration 41

Your turn!

If 10.0 g NaCl (58.443 g/mol) are dissolved in 75.0 mL. What is the molarity?

a) 0.133 M

b) 2.28 M

c) 7.5 M

d) 0.00228M

e) None of the above

4.6. The composition of a solution is described by its concentration 42

Dilution

• Adding solvent to a solution creates a less concentrated solution

• moles of solute do not change, hence CstockVstock= CnewVnew

C=concentration V=volume

• Using volumetric glassware ensures that the volumes are known precisely

4.6. The composition of a solution is described by its concentration 43

Dilution allows molecules more room

• Adding solvent does not change how many moles of solute are present

• The total volume does change• The concentration of the solution is decreased while

the actual amount of solute is unchanged

4.6. The composition of a solution is described by its concentration 44

Learning Check

• What volume of 12.1M HCl are needed to create 250. mL of 3.2 M HCl?

• 25 mL of 6 M HCl are diluted to 500 mL with water. What is the molarity of the resulting solution?

newVmL 500 M6mL 25 0.3 M

3.2MmL 250. M12.1Vstock 66 mL

4.7. Molarity is used for problems in solution stoichiometry 45

• What volume of 2M HCl is needed to react 25.2 g Na2CO3 (MM=105.9887) completely?

• How many moles of BaSO4 will form if 20.0 mL of 0.600 M BaCl2 is mixed with 30.0 mL of 0.500 M MgSO4?

• BaCl2(aq) + MgSO4(aq) →BaSO4(s) + MgCl2(aq)

Solution stoichiometry

L 0.238HCl mol 2

L

CONa mol 1

HCl mol 2

105.9887g

CONa mol 1

1

CONa g 25.2

32

3232

44

44

42

42

BaSO mol 0150.0MgSO mol 1

BaSO mol 1

L

MgSO mol 0.500

1

L 0.0300

BaSO mol 0.0120BaCl mol 1

BaSO mol 1

L

BaCl mol 0.600

1

L 0.0200

0.0120 mol

4.7. Molarity is used for problems in solution stoichiometry 46

Your turn!

What mass of Na2CO3 (MM=105.9887) can be neutralized with 25.00 mL of 3.11 M HCl?

a) 53.0 g

b) 1.65(102) g

c) 8.24 g

d) 4.12 g

e) None of these

4.8. Chemical analysis and titration are applications of solution stoichiometry 47

.

Titration

• Is the controlled addition of one reactant (titrant) to a known quantity of another (titrate) until the reaction is complete

• Often, an indicator is used to signal the reaction completion

• Endpoint: the volume of titrant required to complete the reaction

4.8. Chemical analysis and titration are applications of solution stoichiometry 48

Titration in practice:

4.8. Chemical analysis and titration are applications of solution stoichiometry 49

Solving titration problems

• Write the balanced equation• Calculate the moles of the known component

M ×L = moles or mass/MM=moles

• Use stoichiometry to determine moles of the unknown

• Convert moles to desired quantity

4.8. Chemical analysis and titration are applications of solution stoichiometry 50

Path for working titration problems

4.8. Chemical analysis and titration are applications of solution stoichiometry 51

Learning Check:

• 25.00 mL of HCl are titrated with 75.00 mL of 1.30M Ca(OH)2. What is the concentration of HCl?

• 2HCl(aq) + Ca(OH)2(aq)→CaCl2(aq) + 2H2O(l)

0.02500L

1

Ca(OH) mol 1

HCl mol 2

L

Ca(OH) mol 1.30

1

L 0.07500

2

2

7.80 M HCl

4.8. Chemical analysis and titration are applications of solution stoichiometry 52

Learning Check:

A sample of metal ore is reacted according to the following reaction: Fe(s) + 2H+

(aq) → Fe2+(aq) + H2(g). If

25.00 mL of 2.3M HCl are used, what mass of Fe was in the ore?

1.6gFe mol

g 55.845

H mol 2

Fe mol 1

HCl mol 1

H mol 1

L

HCl mol 2.3

1

L 0.02500