Stage 4 science syllabus – Key areas
1. Accuracy vs Validity vs Reliability
These are often confused, but each has a distinct focus:
Accuracy – How close a measurement is to the true or accepted value.
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Teach through: using correct measuring instruments, zeroing scales,
repeating for precision.
Validity – Whether the investigation tests what it claims to test.
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Must have: only one independent variable, appropriate controls, and
fair testing.
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Example Misconception: Measuring plant growth with different amounts
of water and sunlight = invalid.
Reliability – Consistency of results across repeated trials.
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Teach through: repeating experiments and checking for similar
outcomes.
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If results vary widely, the test may not be reliable.
2. Fair Testing
Involves changing only one variable at a time and keeping all others constant.
Leads directly into discussions of validity.
Could be introduced with:
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A poorly controlled experiment
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A group challenge: "Is this a fair test? Why or why not?"
3. Measuring Error and Uncertainty (Introductory)
Teach students that no measurement is perfect.
Use language like:
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“About 10 seconds”
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“Between 15–20°C”
Introduce basic error margins (e.g. ±1 second or ±0.5 cm)
4. Graphing and Interpreting Data
Using collected data to:
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Plot on line graphs (for continuous data)
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Label axes correctly (independent on x-axis, dependent on y-axis)
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Spot patterns, trends, or anomalies
5. Formulating a Hypothesis
A prediction that links the independent and dependent variables using an
"If...then..." structure.
Teach how to justify hypotheses based on prior knowledge.
1. Working Scientifically Skills
These are explicitly taught and assessed:
Questioning and Predicting: Formulate testable questions and hypotheses.
Planning Investigations: Design fair tests, identify variables, use equipment
accurately.
Conducting Experiments: Safely perform investigations, make accurate
measurements.
Processing and Analysing Data: Collect, represent and interpret data
(tables, graphs, averages, trends).
Problem Solving: Apply scientific knowledge to real-world contexts and
problems.
Evaluating: Assess methods, identify improvements, discuss reliability,
accuracy, validity.
Communicating: Write structured reports, use correct terminology and
representations (e.g. chemical formulas, labelled diagrams).
2. Knowledge and Understanding Strands
Each strand contains key content areas:
Strand
Core Topics
Physical
World
Forces, energy transformations (motion, simple machines,
sound/light)
Earth and
Space
Rock cycle, geological time, Earth's structure, renewable/nonrenewable resources
Living World
Cells, classification, body systems, ecosystems
Chemical
World
States of matter, mixtures, physical/chemical changes,
atoms/elements/compounds
📚 Typical High-Ability Assessment Topics / Questions
In selective or high-performing schools, students are assessed with a mix of inquirybased, analytical, and applied questions. Examples:
🔹 Physical World
Topic: Forces and Energy
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Question: Explain how unbalanced forces affect motion using
Newton’s laws.
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Extension Task: Design a Rube Goldberg machine using 3 types of
energy transformations. Explain each stage with labelled diagrams.
🔹 Chemical World
Topic: Atoms and Elements
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Question: Draw the atomic structure of fluorine and explain why it is
reactive.
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Extension Task: Compare the properties of elements in the same
group and justify trends using atomic structure.
🔹 Living World
Topic: Body Systems
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Question: Describe how the respiratory and circulatory systems work
together during exercise.
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Extension Task: Evaluate how changes to an ecosystem (e.g.
pollution or species removal) disrupt food webs.
🔹 Earth and Space
Topic: Geological Change and Resources
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Question: Describe the rock cycle and the processes that transform
one rock type into another.
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Extension Task: Propose a sustainable solution to a local
environmental issue based on your understanding of natural resources.
🔍 Challenging Inquiry or Research-Based Tasks
These are often used in top-tier schools:
Design an experiment to test how different surfaces affect friction and
evaluate your method.
Create a scientific model or infographic explaining energy transformations in a
rollercoaster.
Analyse a case study (e.g. climate change, coral bleaching, natural disasters)
and apply scientific reasoning to propose mitigation strategies.
Compare Indigenous knowledge systems with Western scientific explanations
in understanding natural phenomena.
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