At 3:00 PM on a sunny October day, South Australia's solar panels generate more electricity than the entire state can use. By 7:00 PM, the Sun has set, the wind has dropped, and demand is peaking. The difference between these two moments — surplus and shortfall — is the central challenge of the energy transition. Storage is the answer. From lithium-ion batteries the size of shipping containers to underground caverns of compressed air, Australia is racing to build the infrastructure that will allow renewable energy to power the nation 24 hours a day. This lesson explores the technologies, the economics, and the engineering of storing energy.
Your phone battery stores about 15,000 joules of energy. A Tesla Powerwall home battery stores about 50 million joules. But the state of South Australia needs billions of joules to keep the lights on overnight.
Before reading on, estimate: How many Tesla Powerwalls would it take to power Adelaide for one night? Adelaide uses about 1,500 MW of electricity at peak. A Powerwall can output 5 kW continuously. Write your estimate and reasoning. You will compare it to real projects at the end of the lesson.
📚 Core Content
Batteries store energy as chemical potential energy. When charging, electrical energy drives a chemical reaction that stores energy in the battery's electrodes. When discharging, the reverse reaction releases electrical energy. Lithium-ion batteries — the same technology in phones and laptops — now power grid-scale storage facilities.
The Hornsdale Power Reserve in South Australia was the world's largest lithium-ion battery when commissioned in 2017. With 150 MW of power output and 194 MWh of storage capacity, it can power 75,000 homes for one hour. But its real value is not duration — it is speed. The battery can respond to grid frequency changes in milliseconds, far faster than any gas turbine. In its first three years of operation, it saved South Australian consumers $150 million by stabilising prices during supply disruptions.
Battery costs have fallen by 90% since 2010. In 2023, grid-scale lithium-ion batteries cost approximately $400 per kWh of capacity. Australia has over 40 grid-scale battery projects under construction, with a combined capacity of 10,000 MWh. However, lithium-ion batteries are best for short-duration storage (1–4 hours). They are not economical for storing energy across multiple days — a limitation that other technologies address.
Pumped hydro energy storage is the oldest and largest form of grid storage, representing 95% of global storage capacity. The concept is elegantly simple: when electricity is cheap and abundant, use it to pump water uphill. When electricity is expensive and scarce, let the water flow back down through turbines to generate electricity.
Pumped hydro is approximately 70–85% efficient — meaning 15–30% of the energy is lost to friction and turbulence. But what it lacks in efficiency, it makes up for in scale and longevity. A pumped hydro facility can store energy for days or even weeks, and the infrastructure lasts 50–100 years.
Snowy 2.0 is the largest pumped hydro project in the southern hemisphere. When complete, it will store 350,000 MWh of energy — enough to power 3 million homes for a week. The project involves building 27 km of tunnels through the Snowy Mountains, connecting the Talbingo Reservoir (lower) to the Tantangara Reservoir (upper) with a 200-metre vertical drop. The $5.9 billion project has faced significant engineering challenges, including difficult geology and environmental concerns, but remains central to Australia's storage strategy.
Hydrogen is the most abundant element in the universe. When burned or used in a fuel cell, it produces only water as a byproduct — no CO₂, no particulates, no pollution. The challenge is that hydrogen does not exist naturally in pure form on Earth. It must be extracted from water or fossil fuels, which requires energy.
Green hydrogen is produced by splitting water (H₂O) into hydrogen and oxygen using renewable electricity — a process called electrolysis. The energy transformation is: electrical → chemical (stored in hydrogen bonds). When the hydrogen is later burned or used in a fuel cell, the reverse occurs: chemical → electrical. Because the only byproduct is water, green hydrogen is genuinely zero-emission across its entire lifecycle — provided the electricity used for electrolysis comes from renewables.
Australia has enormous potential as a green hydrogen exporter. The Pilbara region in Western Australia receives some of the world's most intense sunshine. Solar farms there could generate cheap electricity to produce hydrogen, which could then be exported to Japan and South Korea — countries with limited renewable resources but strong hydrogen strategies. The Asian Renewable Energy Hub, planned for the Pilbara, aims to produce 1.6 million tonnes of green hydrogen annually by 2030.
| Technology | Duration | Efficiency | Cost ($/kWh) | Best For |
|---|---|---|---|---|
| Lithium-ion battery | 1–4 hours | 85–95% | ~$400 | Frequency stability, short peaks |
| Pumped hydro | 6–100 hours | 70–85% | ~$200 | Overnight storage, seasonal |
| Green hydrogen | Days to months | 30–45% | ~$500 | Long-term, transport fuel |
| Compressed air | 2–24 hours | 50–70% | ~$150 | Medium duration, specific geology |
In 2022, a small startup in Adelaide developed a method to store hydrogen in tiny metal beads rather than as compressed gas or liquid. The metal hydride beads can be transported at room temperature in standard shipping containers, eliminating the need for expensive high-pressure tanks or extreme cooling. When hydrogen is needed, the beads are heated slightly, releasing pure hydrogen gas. The technology could transform hydrogen transport: instead of building expensive pipelines, hydrogen could be shipped in containers like any other cargo. The company, H2Store, is now partnering with Japanese firms to test the technology for export — potentially making Australia the world's first "hydrogen bead" exporter.
The Brisbane 2032 Olympic Games will be the first "climate-positive" Olympics. The organising committee has committed to powering all venues with 100% renewable energy, with battery storage at each site. The main stadium will feature a 5 MWh battery system — enough to power the venue for 4 hours off-grid. During events, solar panels on stadium roofs will generate surplus energy, charging the batteries. During evening events, the batteries will discharge, eliminating the need for diesel generators. The Games will also use hydrogen fuel cell buses to transport athletes and officials. This is sports infrastructure leading the energy transition — demonstrating that even the world's largest events can operate without fossil fuels.
Click the best storage technology for each scenario. Consider duration, cost, and feasibility.
Wind speeds vary constantly. The grid needs instant response to prevent frequency fluctuations.
Rainfall is seasonal. Excess water in summer could generate electricity in winter when dams are low.
The fuel must be transported 7,000 km by ship and stored for weeks at the destination.
1 A lithium-ion battery in the Hornsdale Power Reserve, South Australia.
2 The Snowy 2.0 pumped hydro scheme during a charging cycle.
3 Green hydrogen production at a Pilbara solar farm, then use in a Tokyo fuel cell.
Select the best answer for each question. Score 5/5 to unlock the game phase.
1. What is the primary energy transformation that occurs when a lithium-ion battery is charging?
2. Why is pumped hydro particularly valuable for renewable energy systems?
3. Green hydrogen is produced by splitting water using renewable electricity. What is the main advantage of green hydrogen over fossil fuels?
4. A grid operator needs to store excess midday solar energy for use at 7:00 PM. Which storage technology is most appropriate?
5. Snowy 2.0 will store 350,000 MWh of energy. Approximately how many Tesla Powerwalls (each 13.5 kWh) would be needed to store the same amount?
Use clear scientific language. Check the model answers after attempting each question.
Question 1. A pumped hydro facility pumps 500,000 tonnes of water 200 metres uphill using surplus solar energy. Calculate the gravitational potential energy stored. Use g = 9.8 m/s². Show all working.
Question 2. A student claims: "Lithium-ion batteries are the best storage technology because they are the most efficient and fastest to respond. We should only build batteries and forget about pumped hydro and hydrogen." Evaluate this claim, providing at least one argument supporting the claim and at least two arguments challenging it. Use specific evidence from this lesson.
Question 3. Australia aims to reach 82% renewable electricity by 2030. Using what you have learned about renewable generation, storage technologies, and grid stability, explain why storage is essential for this target, and evaluate which combination of storage technologies would be most effective for Australia. Your answer should consider: daily solar cycles, multi-day wind lulls, seasonal variations, geography, and cost.
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