GAS LAWS

Boyle?s law.

By the end of the lesson, the learner should be able to:


State Boyle?s law.
Explain Boyle?s law using kinetic theory of matter.

Teacher demonstration ? Use syringes / pumps to show variation of volume with pressure.
Teacher asks probing questions leading to statement of the law.
Discuss the cause of build-up-in pressure.

Chart
Volume-pressure relationship.

Syringes.

K.L.B. BK III
PP. 1-2

Longhorn Book III
PP 1 -2

GAS LAWS

Boyle?s law: - Equation and graphical representation.

By the end of the lesson, the learner should be able to:
Represent Boyle?s law mathematically and graphically.

Q/A: relation between volume and pressure mathematically and graphically.
Derive the relation P1V1=P2V2, and sketch graphs to illustrate Boyle?s law.
Worked examples.
Assignment.

chart

K.L.B. BK III
PP. 3-4

Longhorn Book III
PP 3-5

GAS LAWS

Boyle?s law: Numerical questions.

By the end of the lesson, the learner should be able to:
Solve further problems involving Boyle?s law.

Supervised exercise: Volume in cm?, m?, litres, and pressure in Pa, mmHg, cmHg, atmospheres.
Assignment.

Calculators.

K.L.B. BK III
PP. 4-5
Longhorn Book III PP 6-8

GAS LAWS

Boyle?s law: Interpretation of graphs.

By the end of the lesson, the learner should be able to:
Plot and intepret graphs involving pressure and volume of gases.

Completing tables and plotting graphs.
Interpret the plotted graphs.
Make deductions from the graphs.

Graph papers.

K.L.B.
BK III
PP. 4-5

GAS LAWS

Charles? law.
Temperature in Degree Celsius and Kelvin. Equation and graphs from Charles? law.

By the end of the lesson, the learner should be able to:

State Charles? law.
Explain Charles? law using kinetic theory of matter.
Convert temperature in degree Celsius to Kelvin and vice-versa.

Teacher demonstration:- To show expansion of air when heated and contraction when pressure is constant.
Explain increase in volume when temperature is raised.
Q/A: - relation between volume and temperature, leading to Charles? law.
Teacher explains inter-conversion of the units.
Students complete a table of temperature in the two units.

Coloured water,
Glass tube,
Warm water,
Cork and
Flask.
student book

.K.L.B.
BK III P. 6

Longhorn Book III PP 9-11

K.L.B.
BK III P. 10

Longhorn Book III P 11

GAS LAWS

Temperature in Degree Celsius and Kelvin. Equation and graphs from Charles? law.

By the end of the lesson, the learner should be able to:
Convert temperature in degree Celsius to Kelvin and vice-versa.

Teacher explains inter-conversion of the units.
Students complete a table of temperature in the two units.

student book

K.L.B.
BK III P. 10

Longhorn Book III P 11

GAS LAWS

Charles? law- equation and graphical representation.

By the end of the lesson, the learner should be able to:
Express Charles? law with equations.

Give a graphical representation of Charles? law.

Derive equations from volume and temperature relationship.

Exposition: - Teacher exposes a volume-temperature graph and extrapolates it to obtain the absolute temperature. The definition of absolute temperature is exposed.

student book

K.L.B. BK III
PP. 6-7

Longhorn Book III P 10

GAS LAWS

Numerical questions on Charles? Law.

By the end of the lesson, the learner should be able to:
Solve numerical problems based on Charles? Law.

Worked examples.
Supervised exercise.

Assignment.

Calculators.

K.L.B.
BK III P. 12

Longhorn Book III PP 12-14

GAS LAWS

Combined Gas Law.
Standard conditions, S.T.P. conditions and R.T.P. conditions.
Diffusion.

By the end of the lesson, the learner should be able to:
Derive the Gas Law.
Derive the combined gas law equation.
Solve numerical problems using the equation.
State standard conditions of temperature and pressure of an ideal gas.
State room temperature and pressure of a gas.
Use standard conditions in problem solving.

Q/A: - Combining Boyle?s and Charles? Laws.
Worked examples.
Exposition of s.t.p. and r.t.p.


Problem solving.

Calculators.
student book
KMnO4 crystals,
Litmus papers.

K.L.B.
BK III P. 12

Longhorn Book III PP 14-16


K.L.B.
BK III P. 14

GAS LAWS

Rates of diffusion.

By the end of the lesson, the learner should be able to:
Compare rates of diffusion of ammonia gas and hydrogen chloride in air.

Teacher demonstration: - To deduce rate of diffusion of ammonia gas and hydrogen chloride.
Q/A: - Students calculate ratio of rates of diffusion of the gases.

student book

K.L.B.
BK III
PP. 18-19
Longhorn Book III 21

GAS LAWS

Graham?s Law.

By the end of the lesson, the learner should be able to:
Carry out numerical tasks.

Solve problems involving RMM, equal volumes of the gases involved.
Supervised practice.
Assignment.

Calculators

K.L.B. BK III
PP. 24-26

Longhorn Book III PP 22-24

THE MOLE

Mole, molar mass and R.A.M.

By the end of the lesson, the learner should be able to:
Define the term mole as a quantity of measurement.
Relate the mole to R.A.M and molar mass.

Discuss various analogies that lead to the definition of the mole.
Expose the meaning of R.A.M., Avogadro?s constant and molar mass.

Chart- table of molar masses of elements.

K.L.B. BK III
PP. 27-31
Longhorn
Book III
PP 34-35

THE MOLE

Number of moles in a substance.
Relative molecular mass & Relative formula mass.

By the end of the lesson, the learner should be able to:
Calculate number of moles in a given mass of a substance.
Define relative molecular mass.
Calculate RMM of a compound.

Worked examples.
Supervised practice.
Q/A: - Review formulae of compounds.
Complete a table of compounds and their molecular / formula mass.

student book
Calculators.

K.L.B .BK III
P. 34
Longhorn
BK III
PP 39-40

K.L.B.BK III
PP. 34-35

Longhorn Book III PP 44-60

THE MOLE

Relative molecular mass & Relative formula mass.

By the end of the lesson, the learner should be able to:
Define relative molecular mass.
Calculate RMM of a compound.

Q/A: - Review formulae of compounds.
Complete a table of compounds and their molecular / formula mass.

Calculators.

K.L.B.BK III
PP. 34-35

Longhorn Book III PP 44-60

THE MOLE

Moles and Avogadro?s number.

By the end of the lesson, the learner should be able to:
Calculate number of particles in a given number of moles.

Review standard form of numbers.
Worked examples.
Supervised exercise.

Calculators.

K.L.B.BK III
PP. 3132
Longhorn
Book III
PP 30-31

THE MOLE

Empirical Formula.

By the end of the lesson, the learner should be able to:
Determine empirical formula of a compound given percentage composition by mass.

Worked examples.
Supervised practice.

Assignment.

student book

K.L.B.
BK III P. 43

Longhorn Book III PP 66-71

THE MOLE

Molecular formula.
Concentration of a solution.

By the end of the lesson, the learner should be able to:
Define molecular formula of a compound.
Find molecular formula given percentage composition of a compound by mass.

Define concentration of a solution.
Find concentration of a solution in grams/litre and moles/litre.

Worked examples.

Supervised practice.
Q/A: - Equivalent ratios, e.g. 4g dissolved in 500cm? and
8g in 1 litre.
Worked examples on concentration of solutions.

Calculators.
chart

K.L.B.BK III
P. 45

Longhorn
Book III
PP 73-75

K.L.B. BK III
PP. 46-48

Longhorn Book III PP 76-81

THE MOLE

Molarity of a solution.

By the end of the lesson, the learner should be able to:
Define molarity of a solution.
Find molarity of a solution in M/dm?

Teacher explains that molarity of a solution is given in moles of the solute per litre.
Worked examples.
Supervised exercise.

student book

K.L.B. BK III
PP. 48-49

Longhorn
Book III
PP 76-81

THE MOLE

Preparation of molar solutions.

By the end of the lesson, the learner should be able to:
Define molar solutions.
Prepare molar solutions.

Q/A: - Description of preparation of molar solutions.

Volumetric flasks, teat droppers/wash bottle.
Sodium hydrogen pellets.
Weighing balance.

K.L.B. BK III
PP. 50-51

Longhorn
Book III
PP 78-81

THE MOLE

Calculators on molar solutions.

By the end of the lesson, the learner should be able to:
Solve numerical calculations on molar solutions.
Problems on molar solutions.

Worked examples.
Supervised exercise.
Assignment.

student book

K.L.B. BK III
P 51
Longhorn Book III PP 76-81

THE MOLE

Dilution of solutions.
Stoichiometry of a chemical reaction.
Stoichiometric equations.

By the end of the lesson, the learner should be able to:
Calculate molarity of a solution after dilution.
To determine mole ratio of given reactions.

Group experiments.
Calculations.
Group experiments: - Determine masses, hence moles of reacting CuSO4 solution and iron metal.

student book
CuSO4 solution and iron metal.
student book

K.L.B. BK III
PP. 76-81
K.L.B. BK III
P. 56
Longhorn Book III PP 87-92

THE MOLE

Stoichiometric equations of various reactions.

By the end of the lesson, the learner should be able to:
To investigate and determine Stoichiometric equations of various reactions.

Class experiments.

Problem solving.

student book

K.L.B. BK III
P. 62

Volumetric Analysis.

Apparatus used in titration experiments.

By the end of the lesson, the learner should be able to:
To use and read a pipette and a burette.

Discussion and practical use of the apparatus.
Emphasis is laid on need to sterilize the apparatus after use.

Pipettes
Burettes.

K.L.B. BK III
PP. 63-64
Longhorn
Book III
PP 104-8

Volumetric Analysis.

Apparatus used in titration experiments.

By the end of the lesson, the learner should be able to:
To use and read a pipette and a burette.

Discussion and practical use of the apparatus.
Emphasis is laid on need to sterilize the apparatus after use.

Pipettes
Burettes.

K.L.B. BK III
PP. 63-64
Longhorn
Book III
PP 104-8

Volumetric Analysis.

Titration process.
Titration experiment (Neutralization reaction)

By the end of the lesson, the learner should be able to:
To define titration as a process.
Define a titration end-point.
To carry out a titration experiment and obtain accurate results.

Review by Q/A: -
-Indicators and colour changes.
-Choice of indicators.
-Balanced chemical equations.
Discuss characteristics of a good titre, when an an-end point is attained.

Class experiments: - To neutralize HCl with NaOH solution.
Fill in a table of results.
Find the average base used.

Indicators
Suitable acid and base.
student book

K.L.B.
BK III
PP. 64-67

Longhorn
Book III
PP 108-114

K.L.B. BK III
P. 66

Longhorn Book III PP 108-114

Volumetric Analysis.

Titration experiment (Neutralization reaction)

By the end of the lesson, the learner should be able to:
To carry out a titration experiment and obtain accurate results.

Class experiments: - To neutralize HCl with NaOH solution.
Fill in a table of results.
Find the average base used.

student book

K.L.B. BK III
P. 66

Longhorn Book III PP 108-114

Volumetric Analysis.

Titration experiment (Neutralization reaction)

By the end of the lesson, the learner should be able to:
To carry out calculations from experimental results.

Step-by-step calculations.

Calculators.

K.L.B. BK III
P 66
Longhorn Book III PP 108-114

Volumetric Analysis.

Basicity of an acid.
Standardization of HCl.

By the end of the lesson, the learner should be able to:
To define basicity of an acid.

Complete a table of number of replaceable hydrogen ions of an acid; hence define basicity of an acid.
Write corresponding ionic equations.

student book
Dilute HCl, Na2CO3 solutions.

K.L.B. BK III
P. 73

Volumetric Analysis.

Concentration of HCl.
Redox Titration Reactions.

By the end of the lesson, the learner should be able to:
To calculate concentration of HCl from experimental results.
To standardize a solution with an iron (II) salt.

Calculations & supervised practice.
Experiment and calculations.

Potassium Magnate
(VII)

K.L.B. BK III
PP. 74-75
K.L.B. BK III
PP. 74-75

Longhorn
Book III
PP 114-115

Volumetric Analysis.

Water of crystallization.

By the end of the lesson, the learner should be able to:
To determine amount of water of crystallization in ammonium iron sulphate crystals.

Teacher exposes the formula of water of crystallization.
Class experiment.
Filling in a table of results.

Ammonium
Iron (II)
Sulphate crystals.
Dilute sulphuric (VI) acid.

K.L.B. BK III
P. 76

Volumetric Analysis.

Water of crystallization.
Formula mass of ammonium iron (II) sulphate.

By the end of the lesson, the learner should be able to:
To determine amount of water of crystallization in ammonium iron sulphate crystals.
To find formula mass of ammonium iron (II) sulphate.

Teacher exposes the formula of water of crystallization.
Class experiment.
Filling in a table of results.
Calculations from experimental results.

Ammonium
Iron (II)
Sulphate crystals.
Dilute sulphuric (VI) acid.

student book

K.L.B. BK III
P. 76
K.L.B. BK III
PP. 76 -77

Volumetric Analysis.

Formula mass of a given salt.

By the end of the lesson, the learner should be able to:
To solve numerical problems involving water of crystallization.

Problem solving from sample results.

student book

K.L.B. BK III
P.77

Volumetric Analysis.

Atomicity of gases.
Mass and volume of gases.

By the end of the lesson, the learner should be able to:
To define atomicity of gases.

Review by Q/A atoms and molecules; hence the definition.
Discuss a table of gases and their atomicity.

student book
Lubricated syringes
Oxygen/
CO2.

K.L.B. BK III
PP. 78 -80
Longhorn BK III PP 126-128

Volumetric Analysis.

Molar gas volume.

By the end of the lesson, the learner should be able to:
To define molar gas volume.

Use the above results to describe volume of one mole of a gas.
Discuss molar gas volume at R.T.P and S.T.P conditions.

student book

K.L.B. BK III
79 ? 80
Longhorn
Book III
PP 126-127

Volumetric Analysis.

Combining volumes of gases.
Gay Lussac?s Law.

By the end of the lesson, the learner should be able to:
To compare combining volumes of two reacting gases.
To state Gay Lussac?s Law.
To compare Gay Lussac?s Law with Avogadro?s Law.
To solve numericals using Gay Lussac?s Law.

Teacher demonstration: - Determining volumes of reacting gases; hence deduce volume rations.
Teacher exposes the law; and compares it with Gay Lussac?s Law.
Worked examples.
Supervised practice.

student book

K.L.B BK III
P. 82
K.L.B. BK III
P. 85

Longhorn
Book III
PP 129-131

Volumetric Analysis.

Gay Lussac?s Law.

By the end of the lesson, the learner should be able to:
To state Gay Lussac?s Law.
To compare Gay Lussac?s Law with Avogadro?s Law.
To solve numericals using Gay Lussac?s Law.

Teacher exposes the law; and compares it with Gay Lussac?s Law.
Worked examples.
Supervised practice.

student book

K.L.B. BK III
P. 85

Longhorn
Book III
PP 129-131