1. Chemistry overview for years 3 to 5
The subject-group overviews show the units taught in each year in each discipline. They include the unit title, key and related concepts, global contexts, statements of inquiry,
objectives, ATL skills and the content (if any).
For years 1 and 2, please see the âModular sciences overviewâ.
Year 3
Unit title and
teaching hours
Key concept
Related
concept(s)
Global context
Statement of
inquiry
Objectives ATL skills Content
Atomic structure
15 hours
Systems Models
Evidence
Personal and cultural
expression: the ways in
which we discover and
express ideas
Models are
created and
modified over
time to express
new ideas formed
by experimental
evidence.
A Thinking: critical
thinking
Thinking: transfer
Communication:
communication
Research:
information literacy
Research: media
literacy
Atomic models: Thomson, Rutherford and Bohr
Subatomic particles: the electron, proton and neutron
and their characteristics
Introduction to bonding ionic, covalent, and
metallic bonds. How electrons are used differently in
each type of bond. Simple models to demonstrate
each type
Simple quark theorywhich quarks make up
neutrons and protons and the models used to
demonstrate this
Simple outline of the strong interaction that operates
within atomic nuclei
Electronic configurations of atoms
Energy and chemical
change
15 hours
Change Interaction
Consequences
Scientific and technical
innovation: the impact
of scientific and
technological advances
on communities and
environments
A change in
matter is a
consequence of
energy
differences
between
substances.
Scientists and
technicians make
use of this to
create a range of
innovative
products.
B
D
Thinking: critical
thinking
Self-management:
reflection
Thinking: creative
thinking
Communication:
communication
Self-management:
organization
Research:
information literacy
Research: media
literacy
The law of conservation of mass
Physical change, chemical change, reactant,
product, combustion
Definition of the terms âcatalystâ and âprecipitateâ
Writing word and symbol equations
Importance of the subscripts (and coefficients) in
equations
Changes in matter in terms of physical changes and
chemical changes and the types of evidence that
identify a chemical change from a physical change
and how this is related to energy change
Types of chemical reaction: single-/double-
displacement reaction, decomposition, neutralization,
synthesis, combustion reaction, endothermic and
2. Unit title and
teaching hours
Key concept
Related
concept(s)
Global context
Statement of
inquiry
Objectives ATL skills Content
exothermic reactions
Identify the names and formulas for common
laboratory acids and alkalis.
Balancing chemical equations (Limited to simple
compounds and elements or counting
atoms/particles in a diagrammatic problem)
Chemistry in the automobile industry: common
chemical reactions (airbags, semiconductors,
catalytic converters)
Concept that chemical potential energy is stored
within compounds and that it can be released in a
controlled manner to do work or produce heat
Solutions
15 hours
Relationships Evidence
Form
Globalization and
sustainability: the
relationship between
local and global
processes
The formation of
a solution
provides
evidence of a
relationship
between the
natures of
substances.
B
C
Thinking: critical
thinking
Social:
collaboration
Communication:
communication
Self-management:
organization
Self-management:
affective
Research:
information literacy
Polar molecules are electrically neutral but have a
partially positive end and a partially negative end.
Water, ammonia and DNA are polar molecules.
Water molecules are attracted to each other by
âhydrogen bondsâ, which are really just forces of
attraction.
The attraction between molecules at the surface of a
liquid is called surface tension.
Because âhydrogen bondsâ are relatively strong,
water has a high boiling point for a covalent
substance.
Solutions are homogeneous mixtures that can be
solid, liquid or gas. Metal alloys are solid solutions.
Air is a gaseous solution. Aqueous solutions are
solutions that have water as the solvent.
The substance being dissolved is called the solute;
the substance doing the dissolving is called the
solvent.
The amount of a substance that can dissolve in a
liquid (at a particular temperature) is called the
solubility of the substance.
Each substance has a different solubility, which
depends on its interaction with water.
Solutions are said to be saturated when no more
solute can be dissolved.
Polar solvents dissolve polar and ionic solutes. Non-
polar solvents (organic compounds) dissolve non-
3. Unit title and
teaching hours
Key concept
Related
concept(s)
Global context
Statement of
inquiry
Objectives ATL skills Content
polar solutes like dissolves like.
The concentration of a solution tells us how much
solute has been dissolved in the solvent. The units of
concentration are grammes of solute per millilitre of
solvent. A concentrated solution contains more
solute than a dilute solution.
Some gases can dissolve in water. Whether or not
the gas will dissolve depends on the interaction
between the gas molecules and the water molecules.
More gas can dissolve in cold water than in hot
waterfor example, cold soda.
Electrolytes are solutions that can conduct electricity.
They are created by dissolving a salt, acid or base in
water.
A suspension is a mixture of two substances, one of
which is finely divided and is dispersed in the other.
A colloid is a type of mixture intermediate between a
homogeneous mixture (also called a solution) and
a heterogeneous mixture and also has properties
that are intermediate between the two.
An emulsion is a suspension of two liquids that do
not usually mix together.
Acids and bases
20 hours
Relationships Function Fairness and
development: rights
and responsibilities
The strength of
acids and bases
is related to the
function of the
degree of
dissociation and
determines how
they should be
used and
disposed of.
A
B
C
Thinking: critical
thinking
Thinking: creative
thinking
Research: media
literacy
Research:
information literacy
Self-management:
organization
Self-management:
affective
Communication:
communication
Social:
collaboration
Definitions of acids and bases (Arrhenius and
BrønstedâLowry)
pH scale
Indicators (litmus, universal, phenolphthalein)
Conductivity
Concentrated, diluted, strong and weak acids and
bases
Household detergents
4. Unit title and
teaching hours
Key concept
Related
concept(s)
Global context
Statement of
inquiry
Objectives ATL skills Content
Environmental
cycles
15 hours
Relationships Balance
Transformation
Scientific and technical
innovation: the impact
of scientific and
technological advances
on communities and
environments
Scientific and
technological
advances are
impacting upon
the naturally
balanced
relationships
provided by the
effective
transformations
in environmental
cycles.
D Thinking: critical
thinking
Self-management:
reflection
Communication:
communication
Social:
collaboration
Self-management:
organization
Research:
information literacy
Research: media
literacy
Importance of carbon, nitrogen and water
Water cycle
Treatment and recycling of water
Carbon cycle
Nitrogen cycle
Nitrogen-fixing
Year 4
Unit title and
teaching hours
Key concept
Related
concept(s)
Global context
Statement of
inquiry
Objectives ATL skills Content
Periodic trends
15 hours
Relationships Change
Form
Function
Orientation in space
and time: discoveries
The form of the
periodic table is
evolving due to
knowledge-
challenging
discoveries, thus
enhancing its
function of
showing trends in
the physical and
chemical
properties of the
elements.
A Thinking: critical
thinking
Thinking: transfer
Thinking: creative
thinking
Communication:
communication
Self-management:
organization
The periodic table shows the positions of metals,
non-metals and metalloids.
Metals tend to lose electrons and so they form
cations. Non-metals tend to gain electrons so they
form anions.
Elements in a group have the same oxidation state
and therefore similar chemical properties.
Shielding is the decrease in attraction between an
electron and the nucleus in any atom with more
than one electron shell.
⢠As the number of electron shells
increases, shielding increases.
⢠No change occurs as you move across a
period.
Effective nuclear charge is the positive charge
experienced by the electrons due to the charges
in the nucleus.
5. Unit title and
teaching hours
Key concept
Related
concept(s)
Global context
Statement of
inquiry
Objectives ATL skills Content
⢠No change occurs as you move down a
group.
⢠The charge increases from left to right
across a period because protons are
being added to the nucleus.
Vertical and horizontal trends in the periodic table
exist for atomic radius, ionization energy and
electronegativity.
Atomic radius is the distance between the nuclei of
two atoms of the same element, or the size of an
atom. The atomic radius:
⢠increases as you move down a group
because more electron shells are being
added that are further away from the
nucleus
⢠decreases as you move across a period.
Ionization energy is the amount of energy it takes
to remove the most loosely held electron from an
atom. The ionization energy:
⢠decreases as you move down a group
because of shielding
⢠increases as you move across a period
because the electrons are more tightly
held to the nucleus due to the effective
nuclear charge.
Electronegativity is the tendency of an atom in a
bond to pull electrons towards itself. The
electronegativity:
⢠decreases as you move down a group
because the atom has a weaker ability to
accept electrons
⢠increases as you move across a period
because the charge on the nucleus
becomes stronger and so the atom can
attract more electrons.
Properties of fluorine and its use in municipal
water
6. Unit title and
teaching hours
Key concept
Related
concept(s)
Global context
Statement of
inquiry
Objectives ATL skills Content
Stoichiometry
20 hours
Systems Balance
Conservation
Scientific and technical
innovation: how
humans use their
understanding of
scientific principles
The scientifically
constructed
systems for
balancing
chemical
equations require
the numbers and
types of atoms to
be conserved.
B
C
Thinking: critical
thinking
Thinking: creative
thinking
Social: collaboration
Communication:
communication
Communication:
collaboration
Self-management:
organization
Research:
information literacy
Communication:
media literacy
Concept of the mole
Avogadroâs number
Relative molecular mass and relative atomic mass
Empirical and molecular formula
Percentage composition
Stoichiometric calculations
Solutions and problems involving concentrations
Gas laws
10 hours
Relationships Movement
Conditions
Scientific and technical
innovation: how
humans use their
understanding of
scientific principles
Humans can
manipulate the
conditions
impacting upon
gas particles,
thereby
determining their
movement.
C Thinking: critical
thinking
Thinking: reflection
Research:
information literacy
Social: collaboration
Kinetic molecular theory
Conversions for temperature and pressure
Daltonâs law
Boyleâs law
Charlesâ law
Ideal gas law
Graphing and calculations
Standard temperature and pressure
Redox reactions
20 hours
Systems Transfer
Balance
Scientific and technical
innovation: how
humans use their
understanding of
scientific principles
Designers use
the balanced
systems
maintained by the
transfer of
electrons in redox
reactions to
develop a range
of products.
B
C
D
Thinking: critical
thinking
Thinking: creative
thinking
Self-management:
reflection
Social: collaboration
Communication:
communication
Self-management:
organization
Definition of oxidation and reduction (electron
transfer)
Rules for assigning oxidation numbers
Definition of oxidising agent and reducing agent
Half reactions
Electrochemistry (The study of the interchange of
chemical and electrical energy)
Electrochemical cells: voltaic cells (spontaneous)
Reactivity series
Factors (for example, concentration, types of
7. Unit title and
teaching hours
Key concept
Related
concept(s)
Global context
Statement of
inquiry
Objectives ATL skills Content
Research:
information literacy
Research: media
literacy
electrode) that effect cell voltage
Electrolysis reactions
Electrolytic cells and factors (for example,
concentration of solutions, temperature, types of
solutions) that effect electrolysis reactions
Applications of redox reactions (for example,
batteries, purification of metals, galvanizing)
Food chemistry
15 hours
Change Culture
Influences
Balance
Conditions
Identities and
relationships: personal
health
A personâs health
is influenced by
cultural and
conditional
changes to his or
her diet.
A
D
Thinking: critical
thinking
Thinking: creative
thinking
Self-management:
reflection
Thinking: transfer
Communication:
communication
Research:
information literacy
Research: media
literacy
Determining caloric values of food
Macromolecules and enzymes
Colour and flavour
Shelf life
Additives
Food technology
Year 5
Unit title and
teaching hours
Key concept
Related
concept(s)
Global context
Statement of
inquiry
Objectives ATL skills Content
Chemical
nomenclature
15 hours
Systems Patterns
Development
Models
Globalization and
sustainability: the
interconnectedness of
human-made systems
and communities
Systems for
explaining the
world are
constructed by
observing
patterns.
A Thinking: critical
thinking
Thinking: transfer
Communication:
communication
Self-management:
organization
Chemical formula review
Naming of simple compounds
Naming of ionic compounds
Naming of positive ions
Naming of negative ions
Naming of polyatomic ions
Naming of acids: organic and inorganic
IUPAC nomenclature
Naming of organic compounds (aliphatic and
8. Unit title and
teaching hours
Key concept
Related
concept(s)
Global context
Statement of
inquiry
Objectives ATL skills Content
aromatic hydrocarbons, alkanes, alkenes)
Bonding
15 hours
Relationships Interactions
Nature
Models
Globalization and
sustainability: the
interconnectedness of
human-made systems
and communities
Scientists use
bonding models
to explain the
nature of
interactions
between different
types of particles.
A
D
Thinking: critical
thinking
Self-management:
reflection
Social: collaboration
Self-management:
organization
Communication:
communication
Research:
information literacy
Research: media
literacy
Self-management:
affective
Bonds are formed to achieve stability.
Positive ions (cations) form by metals losing
valence electrons.
Negative ions (anions) form by non-metals gaining
electrons.
The number of electrons lost or gained is
determined by the electron configuration of the
atom.
The ionic bond is due to electrostatic attraction
between oppositely charged ions.
A covalent bond is the electrostatic attraction
between a shared pair of electrons and the
positively charged nuclei.
Single, double and triple covalent bonds involve
one, two and three shared pairs of electrons,
respectively.
Lewis (electron dot) structures show all the
valence electrons in a covalently bonded species.
The âoctet ruleâ refers to the tendency of atoms to
gain a valence shell with a total of eight electrons.
Some atoms have incomplete octets of electrons,
for example Be and B.
Carbon and silicon form giant covalent/network
covalent/macromolecular structures.
Intermolecular forces include London dispersion,
dipoleâdipole forces and hydrogen bonding.
A metallic bond is the electrostatic attraction
between a lattice of positive ions and delocalized
electrons
Alloys usually contain more than one metal and
have enhanced properties.
Thermochemistry
20 hours
Change Energy
Process
Scientific and technical
innovation: how
humans use their
understanding of
scientific principles
Physical and
chemical
processes
involve energy
changes that can
be used to create
a range of
B
C
D
Thinking: critical
thinking
Self-management:
reflection
Thinking: transfer
Energy changes (transformation)
Temperature and heat
Temperature as the measure of the average
kinetic energy of particles in a system
Describing the difference between physical and
9. Unit title and
teaching hours
Key concept
Related
concept(s)
Global context
Statement of
inquiry
Objectives ATL skills Content
products and
solutions that
impact on
humankind and
the environment.
Social: collaboration
Communication:
communication
Self-management:
organization
Research:
information literacy
chemical changes in terms of energy
Qualitative and quantitative measurements.
Units of energy
Exothermic and endothermic processes
Combustion as an exothermic reaction
Difference between complete and incomplete
combustion
The role of fossil fuels in our modern society
Bond breaking as an endothermic and bond
making as an exothermic process
Different types of insulators
Heat capacity and specific heat capacity
Using calorimetry to measure changes in heat
(enthalpy) and determine the enthalpy change for
a chemical process
Calculating energy change in chemical reactions
per unit mass or mole of substance using
experimental data
Concept of equipment accuracy
Kinetics and
equilibrium
20 hours
Relationships Balance
Reaction
Scientific and technical
innovation: the natural
world and its laws
Equilibrium is the
state of balance
attained when
opposing reaction
rates become
equal.
A
B
C
Thinking: critical
thinking
Thinking: creative
thinking
Thinking: transfer
Communication:
communication
Self-management:
organization
Self-management:
affective
Research:
information literacy
Reaction rate and collision theory
Factors affecting the rate of reaction: nature of
reactants, concentration, surface area, catalyst,
temperature
Equilibrium
⢠Physical
⢠Chemical
⢠Le Chatelierâs principle: concentration,
temperature and pressure changes,
effect of a catalyst
10. Unit title and
teaching hours
Key concept
Related
concept(s)
Global context
Statement of
inquiry
Objectives ATL skills Content
Organic chemistry
10 hours
Change Form (Structure)
Energy
Orientation in space
and time: turning points
in humankind
In order for
structure and
energy to
continue driving
change, finite
fossil fuels will
need to be
replaced by
renewable raw
materials.
B Thinking: critical
thinking
Thinking: creative
thinking
Self-management:
affective
Social: collaboration
Self-management:
reflection
Identification of the following: alkane, alkene,
alkyne, alcohol, aldehyde, ketone, carboxylic acid
Nomenclature for straight-chain organic molecules
Combustion reactions
Fossil fuels
