Year 9 Science Unit 3 — Energy Block 2: Sources ⏱ ~40 min Lesson 12 of 24

Renewable Energy Sources

On a single sunny afternoon in October 2023, renewable energy powered 68% of Australia's entire electricity grid — a record that would have seemed impossible a decade ago. From the Snowy Mountains to the Nullarbor Plain, Australia is undergoing an energy revolution. Solar panels on suburban roofs, wind turbines spinning above sheep paddocks, and hydroelectric dams in mountain valleys are replacing coal-fired power stations. This lesson explores how these technologies harvest energy from nature's own engines — the Sun, the wind, and flowing water.

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Think First

Look around your neighbourhood. How many houses have solar panels on their roofs? Have you ever driven past a wind farm? Does your state use more coal, gas, or renewables?

Before reading on, estimate what percentage of Australia's electricity currently comes from: (a) coal, (b) natural gas, (c) solar, (d) wind, (e) hydro. Write your estimates as percentages that add to 100%. You will compare them to real data at the end of the lesson.

📖 Know

The main renewable energy sources: solar, wind, hydro, bioenergy, geothermal
That renewable sources are naturally replenished
Australia's current energy mix and renewable targets

💡 Understand

How each renewable technology converts energy into electricity
Why different regions suit different renewables
The advantages and limitations of each source

🔧 Can Do

Describe energy transformations in renewable systems
Compare renewable and non-renewable sources
Evaluate energy choices for different Australian locations

📚 Core Content

🇦🇺 Australia's Electricity Mix (2024)

☀️ Solar Power

Harvesting the Sun's energy

Australia receives more solar energy per square metre than any other continent. In fact, the solar energy striking Australia in a single day is more than the country's total annual energy consumption. The challenge is capturing it efficiently.

Solar photovoltaic (PV) panels use silicon cells to convert light energy directly into electrical energy. When photons (light particles) strike the silicon, they knock electrons loose. An electric field within the cell pushes these electrons through a circuit, creating direct current (DC) electricity. An inverter then converts this to alternating current (AC) for household use.

Modern panels are about 20% efficient — meaning 20% of the light energy becomes electricity, and 80% becomes waste thermal energy that heats the panel. On a 45°C day, panels can reach 70°C, which actually reduces their efficiency. This is why some Australian solar farms now use water cooling systems.

Australian Context

Australia's Solar Boom: Australia has the highest uptake of rooftop solar in the world. Over 3.4 million Australian homes have solar panels — more than one in three households. The largest solar farm in Australia is the New England Solar Farm in NSW, with 720,000 panels producing enough electricity for 250,000 homes. On a clear summer day, solar panels across Australia generate over 10,000 MW — more than all the country's coal power stations combined. The challenge is storage: solar only works when the Sun shines, so batteries and pumped hydro are essential for reliable supply.

💨 Wind Power

Catching the breeze

Wind is simply moving air — and moving air has kinetic energy. Wind turbines capture this kinetic energy and convert it into electricity. A modern wind turbine is an engineering marvel: blades up to 80 metres long, towers 150 metres tall, and generators producing 3–5 MW each.

The physics is elegant: wind pushes on the turbine blades, creating torque that spins a shaft. The shaft turns a gearbox that increases the rotation speed (from ~30 rpm to ~1,500 rpm). The high-speed shaft spins an electrical generator, converting kinetic energy into electrical energy.

Wind turbines are approximately 45% efficient at converting the wind's kinetic energy into electricity. The remaining energy becomes sound, turbulence, and thermal energy in the gearbox. Larger turbines are more efficient because their blades sweep a much larger area, capturing more wind.

Australian Context

South Australia: The Wind State: South Australia now sources over 60% of its electricity from wind power — one of the highest percentages in the world. The Hornsdale Wind Farm (315 MW) and the adjacent Tesla Big Battery (150 MW) form a remarkable partnership: when wind generation exceeds demand, excess energy charges the battery. When the wind drops, the battery discharges instantly, stabilising the grid. In 2023, South Australia ran on 100% renewable energy for several consecutive days, powered entirely by wind and solar with battery backup. The state's coal power stations closed years ago, proving that a major economy can operate without fossil fuel baseload power.

💧 Hydroelectric Power

The oldest renewable, still the most efficient

Humans have used water wheels for over 2,000 years. Modern hydroelectric turbines are vastly more sophisticated, but the principle is identical: falling water has gravitational potential energy. Let it fall, and that energy becomes kinetic energy. Pass the moving water through a turbine, and the kinetic energy spins a generator to produce electricity.

Hydroelectric power is the most efficient form of electricity generation, with turbines converting up to 90% of the water's energy into electricity. The key equation is the same one from Lesson 05: Eₚ = mgh. The greater the height of the dam and the more water flowing through, the more power is generated.

Australian Context

The Snowy 2.0 Scheme: When complete, Snowy 2.0 will be the largest pumped-hydro project in the southern hemisphere. It works like a giant battery: when renewable energy is abundant (midday solar), water is pumped uphill from a lower reservoir to a higher one, storing gravitational potential energy. When demand peaks (evening), the water flows back down through turbines, generating electricity. The system can store 350,000 MW·h of energy — enough to power 3 million homes for a week. This addresses the biggest challenge of renewables: intermittency. The Sun does not shine at night, and the wind does not always blow. Pumped hydro stores energy when supply exceeds demand and releases it when needed, making a 100% renewable grid possible.

🌍 Other Sources

Bioenergy, geothermal and the renewable comparison

Solar, wind and hydro dominate Australia's renewable mix, but two other sources play important roles.

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Bioenergy

Energy from organic matter: sugarcane waste (bagasse) in Queensland, landfill gas, and wood waste. When plants grow, they capture solar energy through photosynthesis and store it as chemical energy. Burning this biomass releases that energy. Bioenergy is considered renewable because new plants can be grown to replace those harvested. Australia produces about 3,500 GWh of bioenergy annually — enough to power 500,000 homes.

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Geothermal

Energy from Earth's internal heat. Australia has significant geothermal potential in the Cooper Basin (South Australia) and the Great Artesian Basin. Water is pumped deep underground where rocks are hot (up to 250°C), then brought back up as steam to drive turbines. While still experimental in Australia, geothermal could provide reliable baseload power — unlike solar and wind, it operates 24/7.

Comparing Renewable Sources

Source	Efficiency	Pros	Cons
Solar PV	~20%	Abundant in Australia; rooftop scalable; falling cost	Intermittent; needs storage; efficiency drops in heat
Wind	~45%	High efficiency; large scale; works at night	Intermittent; visual/noise impact; location-dependent
Hydro	~90%	Most efficient; reliable; long lifespan	Requires suitable geography; environmental impact
Bioenergy	~30%	Uses waste; reliable; carbon-neutral cycle	Competes with food production; emissions if not managed
Geothermal	~15%	Reliable 24/7; small footprint	Location-limited; high upfront cost; experimental in Australia

Fun Fact — Australian Record

In 2022, the small town of Cobargo on the NSW South Coast — which was devastated by the 2019–2020 bushfires — became one of Australia's first "solar towns." After the fires destroyed the town's grid connection, residents installed over 500 kW of rooftop solar and a community battery. The town now generates more electricity than it uses, exporting surplus to the grid. This transformation from bushfire victim to renewable energy exporter took just 18 months and demonstrates how distributed renewable energy can create resilient, self-sufficient communities.

Sports Science Link

The MCG is Australia's largest stadium and one of its biggest electricity consumers. In 2023, the stadium completed installation of 2,500 rooftop solar panels and a 1.2 MW battery system. On a sunny day during an AFL match, the panels generate enough electricity to power the stadium's lights, scoreboards, and catering facilities. The battery stores excess energy from daytime generation for use during night games. Over a full year, the system reduces the MCG's grid electricity consumption by approximately 25%. This is sports infrastructure leading the energy transition — proving that even 170-year-old stadiums can embrace renewable technology.

Interactive — Build Your Grid

🎮 Design an energy mix for a regional Australian town

You are the energy minister for a town of 10,000 people. Choose what percentage of electricity comes from each source. Your mix must add to 100%. Then see if your grid is reliable, clean, and affordable.

☀️ Solar 30%

💨 Wind 20%

💧 Hydro 10%

🌾 Bioenergy 5%

⚫ Coal 25%

🔥 Gas 10%

Solar Wind Hydro Bio Coal Gas

Copy Into Your Books

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Solar Power

Light → Electrical (+ thermal waste)
Silicon cells knock electrons loose
~20% efficient
Australia: highest rooftop uptake globally

Wind Power

Kinetic (wind) → Kinetic (blades) → Electrical
~45% efficient
Larger = more efficient
SA: 60%+ from wind

Hydroelectric

GPE → Kinetic → Electrical
~90% efficient (most efficient!)
Pumped hydro = energy storage
Snowy 2.0 = largest in southern hemisphere

Other Sources

Bioenergy: chemical → thermal → electrical
Geothermal: thermal → kinetic → electrical
All renewables: naturally replenished
Challenge: intermittency needs storage

Activities

Identify + Apply

Energy Transformation Chains

For each renewable technology, write the complete energy transformation chain. Name the energy form at each stage and the object/substance that has it.

1 Rooftop solar panel on a house in Brisbane.

✏️ Answer in your book.

2 Wind turbine at the Hornsdale Wind Farm, South Australia.

✏️ Answer in your book.

3 Hydroelectric turbine at the Snowy Mountains Scheme.

✏️ Answer in your book.

Evaluate + Recommend

Design a Renewable Town

The remote town of Coober Pedy in South Australia (population 1,800) currently relies on diesel generators for electricity. The town has: abundant sunshine (300+ sunny days/year), moderate but consistent winds, no rivers or dams, and significant underground heat (opal mines reach 45°C at depth). Using what you have learned, recommend a renewable energy mix for Coober Pedy. For each source you recommend, explain why it suits this location and describe the energy transformations involved. For each source you reject, explain why it is unsuitable.

✏️ Design and justify in your book.

Multiple Choice

Quick-Fire Checks

Select the best answer for each question. Score 5/5 to unlock the game phase.

1. Which renewable energy source has the highest efficiency at converting energy into electricity?

AHydroelectric power (~90%)

BWind power (~45%)

CSolar PV (~20%)

DBioenergy (~30%)

2. What is the main challenge that limits the reliability of solar and wind power?

AThey are too expensive to maintain

BThey produce too much electricity for the grid

CThey are intermittent — they only generate when the Sun shines or wind blows

DThey require large amounts of water for cooling

3. In a pumped-hydro energy storage system, when is water pumped uphill?

ADuring peak evening demand, when electricity is most expensive

BWhen renewable energy supply exceeds demand, using surplus electricity

CAt night, when solar panels are not producing

DContinuously, to maintain reservoir levels

4. Which energy transformation correctly describes the operation of a wind turbine?

AChemical → Electrical

BLight → Electrical

CGravitational potential → Electrical

DKinetic (wind) → Kinetic (blades) → Electrical

5. A house in Adelaide installs rooftop solar panels and a home battery. On a sunny afternoon, the panels produce more electricity than the house uses. What happens to the excess energy?

AIt is lost as waste thermal energy in the panels

BIt charges the home battery or is exported to the electricity grid

CIt is automatically converted into gas for cooking

DIt is stored as gravitational potential energy in the house's roof

Written Response

Short Answer Questions

Use clear scientific language. Check the model answers after attempting each question.

3 marks

Question 1. Explain why pumped-hydro energy storage is described as a "giant battery." In your answer, describe the energy transformations that occur when the system is charging (pumping water uphill) and when it is discharging (generating electricity).

✏️ Answer in your book.

Hint: Think about what type of energy is being "stored" in the water at the top of the reservoir. How is this similar to a chemical battery?

4 marks

Question 2. A student claims that because Australia has "unlimited sunshine," solar power alone can meet all of Australia's electricity needs. Evaluate this claim, providing at least one argument supporting the claim and at least two arguments challenging it. Use specific scientific evidence from this lesson.

✏️ Answer in your book.

Hint: Consider solar panel efficiency, the time of day, weather conditions, and the need for energy storage. What happens at night? What about cloudy days?

5 marks

Question 3. South Australia's electricity grid currently operates with over 60% wind power. Some critics argue that this level of wind power makes the grid unreliable. Using evidence from this lesson, explain how South Australia has addressed the reliability challenge, and evaluate whether other Australian states could adopt a similar approach. Your answer should refer to energy transformations, storage technologies, and geographical factors.

✏️ Answer in your book.

Hint: Think about the Hornsdale Wind Farm + Tesla battery combination. Why does the battery solve the intermittency problem? Would this work in Tasmania (lots of hydro) or the NT (lots of sun, little wind)?

Model Answers

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Q1 (3 marks)

Charging: When renewable electricity is abundant (e.g., midday solar surplus), electrical energy is used to pump water from a lower reservoir to a higher one. This converts electrical energy into gravitational potential energy (Eₚ = mgh) of the elevated water. (1 mark)

Discharging: When electricity is needed, water flows downhill through turbines. The gravitational potential energy is converted into kinetic energy of the moving water, which spins turbines connected to generators, converting kinetic energy into electrical energy. (1 mark)

Why like a battery: Both store energy when supply exceeds demand and release it when needed. The elevated water stores energy as gravitational potential energy, just as a battery stores energy as chemical potential energy. Both allow intermittent renewables to provide reliable, dispatchable power. (1 mark)

Marking criteria: (1) Identifies GPE storage during charging. (2) Describes kinetic → electrical during discharge. (3) Explains analogy to battery (stores energy for later use).

Q2 (4 marks)

Supporting argument: Australia receives more solar energy per square metre than any other continent. With over 3.4 million homes already using rooftop solar, the technology is proven at scale. (1 mark)

Challenge 1 — Intermittency: Solar panels only generate electricity during daylight hours. On average, Australia has 8–10 hours of useful sunlight per day. During the other 14–16 hours (and on cloudy days), alternative sources or storage are essential. Without storage, solar cannot meet evening peak demand. (1 mark)

Challenge 2 — Efficiency and land use: Modern solar panels are only ~20% efficient, meaning 80% of sunlight becomes waste thermal energy. Meeting all of Australia's electricity demand (~200,000 GWh/year) would require hundreds of square kilometres of panels, plus extensive battery or pumped-hydro storage infrastructure. The land and resource requirements are enormous. (1 mark)

Conclusion: While Australia's solar potential is exceptional, solar power alone cannot meet all electricity needs without massive storage infrastructure and complementary sources. A diversified mix including wind, hydro, and storage is necessary for reliability. (1 mark)

Marking criteria: (1) Valid supporting argument with evidence. (2) Challenge 1 (intermittency/night). (3) Challenge 2 (efficiency/land/storage). (4) Balanced conclusion recognising need for diversified mix.

Q3 (5 marks)

Reliability challenge: Wind power is intermittent — wind speeds vary and sometimes drop to near zero. A grid with 60% wind cannot rely solely on wind for continuous supply. (1 mark)

How SA addresses it: South Australia pairs large-scale wind generation with battery storage (e.g., Hornsdale Power Reserve, 150 MW) and grid interconnection to other states. When wind generation exceeds demand, excess electricity charges batteries. When wind drops, batteries discharge instantly. The grid also imports electricity from Victoria via interconnector during low-wind periods. Gas turbines provide rapid backup when both wind and batteries are insufficient. (2 marks — must mention at least two of: battery storage, interconnection, gas backup)

Other states — geographical factors: Tasmania could adopt a similar wind + hydro approach because its existing hydro dams can act as natural storage (pump water uphill using wind). The NT and Queensland have abundant solar but less consistent wind, making solar + battery more suitable. WA has excellent wind and solar resources but is geographically isolated, requiring stronger local storage. Each state must design its mix based on its specific renewable resources. (1 mark — references at least one state's geography)

Conclusion: South Australia's approach demonstrates that high renewable penetration is possible with sufficient storage and backup. However, the specific technologies must be matched to each state's resources. No single solution fits all of Australia. (1 mark)

Marking criteria: (1) Identifies intermittency challenge. (2) Describes SA solution (wind + battery/interconnector/gas). (3) Evaluates feasibility for other states with geographical reasoning. (4) Balanced conclusion recognising state-specific solutions. (5) Uses scientific terminology (intermittency, dispatchable, grid interconnection).

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Energy Mix Solar Power Wind Power Hydroelectric Other Sources Build Your Grid

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