All Object Lessons
Science & Nature

The Lithium Battery: Power for the Energy Transition

⏱ 45 minutes 🎓 Primary & Secondary 📚 science, ethics, citizenship, geography, history
Core question How does one battery technology power both your phone and the global energy transition — and what serious questions about mining, supply chains, and the environment come with it?
A lithium-ion battery pack. Lithium batteries power electric vehicles, phones, computers, and renewable energy storage. They are central to the energy transition — but raise serious supply chain and environmental questions. Photo: MaximKhabur / Wikimedia Commons / CC BY-SA 4.0
Introduction

In your pocket right now, there is probably a lithium-ion battery. Inside your phone, your laptop, your electric toothbrush, your e-bike, your wireless headphones — lithium batteries power most of the portable electronics in modern life. Behind the visible products are also lithium batteries powering electric cars, electric buses, electric trucks, electric forklifts, and large-scale renewable energy storage on power grids. The technology is everywhere. The lithium-ion battery was developed through research by three scientists working separately in the 1970s and 1980s. M. Stanley Whittingham, working in Britain, demonstrated the basic concept in 1976. John Goodenough, working at Oxford, identified the cathode material that made high-energy batteries possible in 1980. Akira Yoshino, working in Japan, developed the safe practical battery in 1985. Sony introduced the first commercial lithium-ion battery in 1991. The three scientists shared the 2019 Nobel Prize in Chemistry for this work. Goodenough was 97 years old at the time, the oldest person ever to win a Nobel Prize. The technology has transformed modern life. Smartphones became practical because of lithium batteries. Laptops became truly portable. Electric vehicles became viable for ordinary use. Grid-scale energy storage is making renewable energy more reliable. The energy transition away from fossil fuels depends heavily on this single technology. But the lithium battery raises serious questions. The lithium itself comes mostly from the 'lithium triangle' of Chile, Bolivia, and Argentina, plus Australia and China. Lithium mining requires enormous amounts of water — about 2 million litres per ton of lithium — in some of the driest places on Earth. The Atacama Desert in Chile, the world's largest lithium source, is being slowly drained of its underground water. Cobalt, used in many lithium battery types, comes mostly from the Democratic Republic of the Congo, where mining often involves dangerous conditions and child labour. Battery recycling remains underdeveloped — most lithium batteries today are not properly recycled. The technology is essential for replacing fossil fuels but creates its own environmental and ethical problems. This lesson asks how lithium batteries work, what they have made possible, and what difficult questions come with them.

The object
Origin
Developed through research by John Goodenough (United States/United Kingdom), M. Stanley Whittingham (United Kingdom), and Akira Yoshino (Japan) in the 1970s and 1980s. The first commercial lithium-ion battery was sold by Sony in 1991. The three scientists shared the 2019 Nobel Prize in Chemistry for this work.
Period
Active commercial production from 1991 onwards. Massive expansion since 2010 as electric vehicles became viable. Continuing rapid development of new chemistries.
Made of
Lithium-ion batteries contain a cathode (often lithium cobalt oxide, lithium iron phosphate, or other lithium compounds), an anode (usually graphite), an electrolyte (a lithium salt in organic solvent), and a separator. Various battery types use different specific materials.
Size
Cells range from coin-sized (in watches) to suitcase-sized (in electric vehicles). A typical electric car battery pack contains hundreds or thousands of individual cells. Smartphone batteries are about the size of a credit card.
Number of objects
Many billions of lithium-ion cells are produced each year. As of 2024, global production capacity is over 2,000 GWh annually — enough for about 25 million electric vehicles or many billions of smartphones.
Where it is now
Used worldwide. Major production centres are China (about 75% of global capacity), South Korea, and Japan. Major raw material sources include the 'lithium triangle' of Chile, Bolivia, and Argentina, plus Australia, China, and emerging African producers.
Before you teach this — reflect

Questions for you

  1. The lithium battery is essential for the energy transition but raises serious ethical questions. How will you teach both honestly without taking a simple side?
  2. Some students may have strong views about climate change or electric vehicles. How will you handle this with care?
  3. The technical content involves real chemistry. How will you make this accessible without dumbing down?

Common student difficulties — tick any you have noticed

Discovery sequence
1
Let me explain how a lithium-ion battery works. The battery has four main parts: a cathode (positive electrode), an anode (negative electrode), an electrolyte (a liquid that fills the space between them), and a separator (a thin membrane that prevents the electrodes from touching while allowing ions to pass through). When the battery is charging, energy from outside (from a wall socket or a solar panel) pushes lithium ions out of the cathode, through the electrolyte, and into the anode. The ions are stored in the structure of the anode. This is energy stored in chemical form. When the battery is being used (discharging), the lithium ions flow the other way — out of the anode, through the electrolyte, back to the cathode. As they flow, electrons are released through an external circuit, providing electrical power to the device. The basic chemistry is elegant. Lithium is the lightest metal in the periodic table, the third lightest element overall. It can pack a lot of energy into a small space. Lithium ions are small enough to move easily between electrodes. The chemistry is also reversible — the battery can be charged and discharged many times. Different lithium-ion batteries use different specific cathode materials. Lithium cobalt oxide (LCO) gives high energy density and is used in phones and laptops. Lithium iron phosphate (LFP) is safer and longer-lasting; used in many electric vehicles and grid storage. Nickel-manganese-cobalt (NMC) batteries are common in electric cars. Each type has different properties. Why might one chemistry become so dominant in modern life?
Points to consider (for the teacher)

Because the combination of properties is unmatched. Lithium-ion batteries are light (because lithium is light), have high energy density (a lot of energy in a small volume), can be charged thousands of times, and can be made in any shape needed. The combination is remarkable. Older battery technologies — lead-acid (used in car starter batteries since the 1860s), nickel-cadmium, nickel-metal-hydride — could not match this combination. Lithium-ion has dominated portable electronics since the late 1990s and electric vehicles since about 2010. The chemistry continues to improve. Newer types like solid-state batteries (using solid electrolytes instead of liquid) may eventually replace current designs. Sodium-ion batteries (using cheaper and more abundant sodium instead of lithium) are also being developed. But for now, lithium-ion is the foundation of the energy transition. Without it, modern smartphones, laptops, and electric cars would not exist in their current forms. Students should see that 'one technology powering the world' is unusual but real. The lithium-ion battery is one of the clearest cases. The Nobel Committee recognised this in 2019 by awarding the chemistry prize jointly to the three scientists who developed it.

2
The development of the lithium-ion battery happened over decades. M. Stanley Whittingham was working at Exxon (the oil company) in the early 1970s when he made a crucial breakthrough. He was looking for energy storage technologies that did not depend on oil — ironic given his employer. He developed the first lithium battery using titanium disulfide as the cathode and lithium metal as the anode. The battery worked but had safety problems — pure lithium metal can catch fire. John Goodenough, working at Oxford in 1980, identified a much better cathode material: lithium cobalt oxide. This material allowed higher voltage and more energy storage. Goodenough did not patent his discovery in his own name (a decision that may have cost him hundreds of millions of dollars personally). The discovery became the basis of all subsequent lithium-ion battery technology. Akira Yoshino, working at the Japanese company Asahi Kasei in 1985, solved the safety problem. He replaced the dangerous lithium metal anode with a graphite anode that could store lithium ions safely. This was the breakthrough that made commercial lithium-ion batteries practical. Sony introduced the first commercial lithium-ion battery in 1991, using Goodenough's cathode and Yoshino's anode design. The early batteries were used in camcorders. By the late 1990s, they powered the new generation of smaller mobile phones and laptops. By 2010, they were powering the first practical electric vehicles. In 2019, the Nobel Prize in Chemistry was awarded jointly to Goodenough (then 97), Whittingham (77), and Yoshino (71). Goodenough became the oldest person ever to win a Nobel Prize. He died in 2023 at age 100, having continued to work on battery research until very near the end of his life. Why might one technology require contributions from multiple scientists across different countries?
Points to consider (for the teacher)

Because complex technologies usually do. The lithium-ion battery required a working battery concept (Whittingham), a high-energy cathode material (Goodenough), and a safe anode design (Yoshino). No single person developed all three. Each scientist built on the others' work. The same is true of many major technologies. The integrated circuit was developed independently by Jack Kilby and Robert Noyce. The telephone was developed by Alexander Graham Bell, Antonio Meucci, Elisha Gray, and others working in parallel. The light bulb was developed by Thomas Edison, Joseph Swan, and many others. 'One inventor' stories are usually simplifications. Real technological development is usually collaborative across countries and decades. The Nobel Committee recognised this with the lithium-ion battery by awarding the prize jointly. Students should see that 'innovation' is usually a long process involving many people. The lithium-ion battery story is one of the clearest examples in modern technology. Three scientists, three countries (UK, US, Japan), three decades of work — and the result has reshaped modern life.

3
The lithium-ion battery is essential to the energy transition away from fossil fuels. Replacing petrol cars with electric ones requires huge amounts of battery capacity. Storing solar and wind energy on the electrical grid requires huge amounts of battery capacity. Electrifying buses, trucks, ships, and even aircraft requires huge amounts of battery capacity. The world is racing to build enough lithium-ion battery factories to meet this demand. Global lithium-ion production capacity reached about 2,000 GWh in 2024 and is growing rapidly. China produces about 75% of the world's batteries. South Korea, Japan, and increasingly the United States and Europe produce the rest. Major battery companies include CATL (China), BYD (China), LG Energy Solution (South Korea), Samsung SDI (South Korea), and Panasonic (Japan). Electric vehicles are the largest and fastest-growing market. Tesla, BYD, Volkswagen, BMW, and dozens of other manufacturers are competing. Some countries — Norway, China, Germany — are seeing rapid electric vehicle adoption. Other countries are slower. The transition is uneven globally. Grid-scale battery storage is the second-largest market. Solar and wind energy are intermittent — solar only works in daylight, wind only when the wind blows. Batteries store the energy for use when needed. The world's largest battery installations are in Australia, California, and Texas, with capacities of hundreds of megawatts. China is building even larger installations. Why might one technology be so central to the energy transition?
Points to consider (for the teacher)

Because it solves the storage problem. Renewable energy is variable. Coal and gas plants can run continuously, but solar and wind cannot. Without storage, you can only use renewable energy when it happens to be generating. With enough storage, you can use renewable energy whenever you need it. The lithium-ion battery is currently the dominant storage technology because of its combination of high energy density, fast charging, long cycle life, and decreasing cost. Battery prices have fallen about 90% since 2010. This price drop has made electric vehicles cost-competitive with petrol cars, made grid storage economically viable, and made many other applications practical. The energy transition was not really possible until lithium-ion batteries became cheap enough. Now they are. The transition is happening. Students should see that 'climate response' is not just about reducing fossil fuels. It is also about replacing them with technologies that work as well or better. The lithium-ion battery has been one of the key enabling technologies. Without it, the transition would be much slower and harder. End the discovery on this idea of enabling technology.

4
The lithium-ion battery is essential, but it raises serious problems. Lithium itself must be mined. The world's lithium comes mostly from the 'lithium triangle' (Chile, Bolivia, Argentina), which together hold about 60% of global reserves. Australia is the largest current producer. China has significant production too. In the lithium triangle, lithium is extracted from underground brines (salty water) by pumping the brine to the surface and letting the water evaporate in large pools. This process uses enormous amounts of water — about 2 million litres per ton of lithium — in the Atacama Desert, one of the driest places on Earth. Indigenous communities in the region have raised serious concerns about water depletion and damage to fragile ecosystems. The Atacameño people have campaigned against expanded lithium mining. Cobalt is another concern. Many lithium-ion batteries (especially in older designs and high-end electronics) contain cobalt as part of the cathode. About 70% of the world's cobalt comes from the Democratic Republic of the Congo (DRC). Some cobalt mining in the DRC is industrial and reasonably safe. But significant amounts come from 'artisanal' mining — small-scale, often unregulated, sometimes involving dangerous conditions and child labour. Investigations have documented children as young as 7 working in cobalt mines. Battery recycling is another issue. Currently, less than 5% of lithium-ion batteries are properly recycled. Most go to landfill, where they eventually leak chemicals into soil and water. Recycling is technically possible but currently not economically viable for most battery types. This is improving — the European Union has passed regulations requiring more battery recycling by 2030 — but the gap between battery production and battery recycling is enormous. What does all this mean?
Points to consider (for the teacher)

That the energy transition is not as clean as it sometimes appears. Replacing petrol cars with electric ones reduces local air pollution and greenhouse gas emissions, both of which are real benefits. But the electric cars require batteries, which require lithium and cobalt mining, which require water and labour and create environmental damage. The transition is necessary — climate change is the larger threat — but it is not free of costs. The same is true of many environmental solutions. Wind turbines require rare earth metals. Solar panels require silicon and various other materials. Hydroelectric dams flood ecosystems. Nuclear power produces radioactive waste. Every energy solution has trade-offs. The lithium-ion battery's trade-offs are particularly visible because lithium and cobalt mining have direct human and environmental costs. Better practices are possible. Lithium iron phosphate batteries (which contain no cobalt) are now common. Battery recycling is improving. New mining methods that use less water are being developed. New battery chemistries (sodium-ion, solid-state) may eventually reduce dependence on lithium and cobalt. The work continues. Students should see that 'good technology' often comes with hidden costs. The lithium-ion battery is essential for the climate response, but the costs of getting the materials are real and need to be addressed. The same kind of honest accounting applies to most modern technologies. End the lesson on this complexity. The transition is necessary. The costs are real. The work of doing both — moving forward and reducing harms — continues.

What this object teaches

The lithium-ion battery is the dominant rechargeable battery technology of the modern world. It was developed by John Goodenough, M. Stanley Whittingham, and Akira Yoshino in the 1970s and 1980s, with the first commercial product sold by Sony in 1991. The three scientists shared the 2019 Nobel Prize in Chemistry. The battery works by moving lithium ions between two electrodes through a liquid electrolyte. When charging, ions move one way; when discharging, they move the other way, releasing energy. Lithium is the lightest metal, allowing high energy density in a small volume. Lithium-ion batteries power smartphones, laptops, electric vehicles, electric tools, and grid-scale energy storage. They are essential to the global energy transition away from fossil fuels. Battery prices have fallen about 90% since 2010, making electric vehicles cost-competitive with petrol cars. Global production is dominated by China (about 75%), with major contributions from South Korea and Japan. The technology raises serious ethical and environmental questions. Lithium mining (especially in the Atacama Desert in Chile) uses enormous amounts of water in dry regions. Cobalt mining (especially in the Democratic Republic of the Congo) often involves dangerous conditions and child labour. Battery recycling is currently underdeveloped, with most batteries going to landfill. Better practices are emerging — cobalt-free LFP batteries are now common, and recycling is improving — but the work of making the energy transition truly sustainable continues. Students should understand both the technology's importance and the real costs that come with it.

DateEventWhat changed
1976Whittingham develops first lithium batteryConcept demonstrated; safety problems remain
1980Goodenough identifies lithium cobalt oxide cathodeHigher voltage and energy density possible
1985Yoshino develops safe graphite anodePractical commercial battery now possible
1991Sony sells first commercial lithium-ion batteryModern portable electronics begin
2010 onwardsBattery prices begin dramatic 10-year declineElectric vehicles become economically viable
2019Goodenough, Whittingham, Yoshino share Nobel PrizeRecognition of one of modern era's most important technologies
TodayGlobal production over 2,000 GWh annuallyEnergy transition dependent on continued battery deployment
Key words
Lithium-ion battery
A rechargeable battery that stores and releases energy by moving lithium ions between two electrodes through a liquid electrolyte. The dominant rechargeable battery technology of the modern world.
Example: A typical smartphone battery stores 10-20 watt-hours of energy and can be charged 500-1,000 times before significant degradation. An electric vehicle battery stores 50-100 kilowatt-hours.
Cathode and anode
The two electrodes of a battery. The cathode is the positive electrode (where lithium ions go during discharge); the anode is the negative electrode (where ions go during charging). Different cathode materials give batteries different properties.
Example: Common cathode materials: lithium cobalt oxide (LCO) for phones, lithium iron phosphate (LFP) for electric vehicles and grid storage, nickel-manganese-cobalt (NMC) for many electric cars. The anode is usually graphite.
Energy density
The amount of energy stored per unit of weight or volume. Lithium-ion batteries have very high energy density compared to older battery technologies, which is why they are used in mobile applications.
Example: A lithium-ion battery stores about 200-300 watt-hours per kilogram. A lead-acid battery (used in car starters) stores about 30-50 watt-hours per kilogram. The lithium-ion battery is 4-10 times better.
Lithium triangle
The region of South America covering parts of Chile, Bolivia, and Argentina that contains about 60% of the world's lithium reserves. Lithium is extracted from underground brines using evaporation pools.
Example: The Atacama Desert in Chile is the world's largest lithium source. The brine extraction uses about 2 million litres of water per ton of lithium produced — a serious concern in one of the driest places on Earth.
Cobalt and the DRC
Cobalt is a metal used in many lithium battery cathode materials. About 70% of the world's cobalt comes from the Democratic Republic of the Congo (DRC). Some DRC cobalt mining involves dangerous conditions and child labour.
Example: Investigations have documented children as young as 7 working in artisanal cobalt mines in the DRC. Major technology companies have pledged to eliminate child labour from their cobalt supply chains; progress has been mixed.
Energy transition
The shift from fossil fuels (coal, oil, gas) to renewable energy sources (solar, wind, hydro). Lithium-ion batteries are essential to this transition because they store renewable energy for use when needed.
Example: Battery storage costs have fallen about 90% since 2010, making the energy transition economically viable. Without continued cost reductions and capacity expansion, the transition would be much slower and harder.
Use this in other subjects
  • Science: Discuss the chemistry of lithium-ion batteries — ion movement, oxidation-reduction reactions, the periodic table position of lithium. The technology is real chemistry, accessible to high school students. Try basic experiments with simple voltaic cells if equipment is available.
  • History: Build a class timeline: Whittingham (1976), Goodenough (1980), Yoshino (1985), Sony commercial battery (1991), price decline (2010 onwards), Nobel Prize (2019). The development is a clear example of long-term basic research producing transformative technology decades later.
  • Geography: On a world map, mark the major lithium sources (Chile, Bolivia, Argentina, Australia, China) and major cobalt sources (Democratic Republic of the Congo). Discuss how natural resource distribution shapes geopolitics.
  • Citizenship: Hold a class discussion: 'How can the energy transition be made fairer for the communities affected by mining?' Discuss specific options: better regulation, international standards, fair-trade certification for batteries, recycling investment, alternative chemistries.
  • Ethics: The lithium battery is essential for fighting climate change but its supply chain raises serious problems. Discuss the difficulty of weighing different harms — climate change versus mining damage versus child labour. There are no simple answers.
  • Mathematics: Battery prices fell from about US$1,200/kWh in 2010 to US$140/kWh in 2023. Calculate the percentage decrease. (About 88%.) Now consider a 50 kWh electric car battery — how much did the battery alone cost in 2010 vs. 2023? (US$60,000 vs. US$7,000.) Discuss why this matters for vehicle adoption.
Common misconceptions
Wrong

Lithium batteries are a recent invention.

Right

The basic technology was developed in the 1970s-80s. The first commercial product was sold in 1991. The technology has been gradually improving for over 30 years. The Nobel Prize for it was awarded in 2019.

Why

Some students assume lithium batteries are very new because they have only become widely used recently. The science behind them is older.

Wrong

Lithium batteries are a clean technology.

Right

They are cleaner than fossil fuels for most applications, but they are not free of environmental and ethical costs. Lithium mining uses enormous amounts of water. Cobalt mining sometimes involves child labour. Battery recycling is currently inadequate. The technology is essential for the energy transition but comes with real costs.

Why

This challenges the simple 'green technology' framing. The truth is more complicated.

Wrong

All lithium-ion batteries are the same.

Right

Different chemistries exist — lithium cobalt oxide (LCO), lithium iron phosphate (LFP), nickel-manganese-cobalt (NMC), and others. Each has different properties (energy density, safety, cost, environmental impact). LFP batteries, for example, contain no cobalt and avoid the supply chain problems of cobalt mining.

Why

This matters because the choice of battery chemistry affects both technical performance and ethical impact.

Wrong

The energy transition is impossible because of battery problems.

Right

The problems are real but solvable. Battery prices continue to fall. Cobalt-free chemistries are spreading. Recycling is improving. Alternative chemistries (sodium-ion, solid-state) are being developed. The transition has costs but is genuinely happening.

Why

'Impossible' is an overstatement that some use to argue against climate action. The truth is that the transition has real challenges but is technically feasible.

Teaching this with care

Treat this lesson as about a real and contested modern technology. Some students may have strong views about climate change, electric vehicles, or environmental issues. Respect their views without endorsing political positions. The lesson should present the technology and the real ethical issues it raises, not advocate for one political position. Be honest about the supply chain problems. Lithium mining and cobalt mining have real human and environmental costs. The Atacameño people in Chile have raised real concerns. Children do work in DRC cobalt mines. These facts should be taught honestly without sensationalism. Be balanced. The lithium battery is essential to fighting climate change. The technology has done real good. The supply chain problems are real but not insurmountable. Both sides should be presented. Be careful with country-specific framing. China dominates lithium battery production but did not invent the technology. Avoid framings that treat Chinese production as inherently problematic. The DRC has serious mining issues but also legitimate industrial mining; avoid presenting all DRC mining as problematic. Be aware that some students may have heritage from countries directly affected by lithium or cobalt mining (Chile, Bolivia, Argentina, DRC, etc). Give them space to share if they want, but do not put them on the spot. The chemistry content is real and challenging. Make it as accessible as possible without dumbing down. The basic concept (ions moving between electrodes) is teachable to high school students. Honour the Nobel laureates. Goodenough, Whittingham, and Yoshino did real long-term research that has reshaped modern life. Mention them by name; their work deserves recognition. Goodenough's persistence into his 90s and his Nobel Prize at 97 are particularly remarkable and worth noting. Finally, end the lesson with realistic optimism about the work continuing. The energy transition is happening, with both progress and real challenges. The lithium battery is at the centre of both.

Check what students have understood

Answer each question in one or two sentences. Use what you have learned about lithium-ion batteries.

  1. How does a lithium-ion battery work?

    It stores and releases energy by moving lithium ions between two electrodes (the cathode and the anode) through a liquid electrolyte. When charging, ions move one way; when discharging (being used), they move the other way, releasing electrical energy. The chemistry is reversible, so the battery can be charged and discharged many times.
    Marking note: Award full marks for any answer that mentions the ions moving between electrodes and the reversibility of the process.

  2. Who developed the lithium-ion battery, and when?

    Three scientists working separately in the 1970s and 1980s: M. Stanley Whittingham (first lithium battery, 1976), John Goodenough (cathode material, 1980), and Akira Yoshino (safe anode design, 1985). The first commercial product was sold by Sony in 1991. The three shared the 2019 Nobel Prize in Chemistry.
    Marking note: Strong answers will mention at least two of the scientists and the rough timeline. The Nobel Prize is a bonus.

  3. Why is the lithium battery essential to the energy transition?

    Because it solves the storage problem for renewable energy. Solar and wind energy are intermittent — only available when the sun shines or wind blows. Batteries store this energy for use when needed. Lithium-ion batteries also enable electric vehicles to replace petrol cars. The energy transition would be much harder without affordable lithium batteries.
    Marking note: Award full marks for any answer that mentions both energy storage and the role in electric vehicles.

  4. What are some of the ethical and environmental concerns with lithium-ion batteries?

    Lithium mining (especially in the Atacama Desert in Chile) uses enormous amounts of water in very dry regions. Cobalt mining (especially in the Democratic Republic of the Congo) sometimes involves dangerous conditions and child labour. Battery recycling is currently underdeveloped, with most batteries going to landfill rather than being properly recycled.
    Marking note: Strong answers will mention multiple specific concerns (water use, child labour, recycling) rather than just one.

  5. Why has the lithium-ion battery price fallen so much since 2010?

    A combination of larger production scale, manufacturing improvements, and competition. Battery prices fell about 90% between 2010 and 2023. This price drop has made electric vehicles cost-competitive with petrol cars and made grid-scale battery storage economically viable. Without this price drop, the energy transition would be much slower.
    Marking note: Award full marks for any answer that gives a rough sense of the scale of the price drop and recognises its importance for the energy transition.
Discuss together

These questions have no single right answer. Talk in pairs or small groups, then share your ideas with the class.

  1. The lithium battery is essential for fighting climate change but its supply chain raises serious problems. How should we weigh these competing concerns?

    This is a hard ethical question. Students may take various positions. Strong answers will see that 'either-or' thinking misses the reality. The transition is necessary because climate change is the larger threat. The supply chain problems are real and need to be addressed. Both can be true. The work involves: better mining practices, alternative chemistries (cobalt-free LFP), better recycling, and continued research. End by saying that this is one of the major ethical challenges of our time. There are no simple answers, but there are better and worse approaches.

  2. Most modern technology is invented in wealthy countries but produced in middle-income countries (China, South Korea) using raw materials from lower-income countries (DRC, Chile, Argentina). Is this a problem, or is it just how the modern global economy works?

    This is a real political and ethical question. Students may argue both ways. Strong answers will see that the structure has costs and benefits. Benefits: lower prices, broader technology access, economic development for producing countries. Costs: workers in producing countries often face poor conditions, environmental damage is concentrated in producing regions, profit accumulates disproportionately in wealthy countries. The structure is being challenged in various ways: trade rules, fair-trade certification, requirements for transparency. The lithium battery story is one specific case of a much larger pattern. End by saying that this is a major question for global governance in the 21st century.

  3. In your country, how much do you think people understand about where lithium and cobalt come from? Should this be taught more widely?

    This is a question about public awareness. Most people do not know much about battery supply chains. Some students will say more education would help; others may see it as too complex for ordinary consumers to think about. Strong answers will see that consumers, governments, and companies all have roles. End by saying that 'who knows what' shapes 'what gets done'. If consumers don't know about supply chain issues, they can't pressure companies to address them. The lithium battery is one specific case of a wider pattern in modern global trade.
Teaching sequence
  1. THE HOOK (5 min)
    Without saying anything about the lesson, ask: 'How many of you have a lithium battery in something you use every day?' Most students will say yes (phones, laptops). Then say: 'These small batteries also power the energy transition away from fossil fuels. We are going to find out about them.'
  2. INTRODUCE THE OBJECT (10 min)
    Describe the lithium-ion battery: a rechargeable battery that stores energy by moving lithium ions between two electrodes. Developed in the 1970s-80s by Whittingham, Goodenough, and Yoshino (Nobel Prize 2019). First commercial product 1991. Pause and ask: 'Why might one battery technology become so dominant?' Listen to answers.
  3. THE CHEMISTRY (15 min)
    On the board, walk through how the battery works: ions move between cathode and anode through electrolyte. Charging stores energy; discharging releases it. Different cathode materials give different properties. End by asking: 'Why does the battery industry have so many different chemistries?'
  4. THE TRADE-OFFS (10 min)
    Tell the supply chain story honestly. Lithium from Atacama Desert (water issues). Cobalt from DRC (sometimes child labour). Recycling currently inadequate. Discuss: how should we weigh these problems against the climate benefits? Strong answers will see this as a real ongoing challenge.
  5. CLOSING (5 min)
    Ask: 'What does the lithium battery teach us about modern technology and its hidden costs?' Take a few honest answers. End by saying: 'The lithium-ion battery is one of the most important technologies of the 21st century. It powers our phones, our laptops, our electric cars, and the energy transition. It also raises real questions about mining, supply chains, and recycling. Both stories are true. The work of making the technology cleaner and fairer continues.'
Classroom materials
Find the Battery
Instructions: In small groups, students list every device in their lives that uses a lithium-ion battery. Phones, laptops, e-readers, electric toothbrushes, e-bikes, headphones, smartwatches, and many more. Each group shares the longest list. Discuss: how dependent are we on this one technology?
Example: In Mr Patel's class, students realised they each had at least 5 lithium batteries in their daily lives. The teacher said: 'You have just understood why this technology matters so much. The same chemistry that powers your phone also powers the world's electric cars and grid storage. Without it, modern life would look very different. Without continued improvements in this technology, the energy transition would be much harder.'
The Trade-Off Discussion
Instructions: On the board, write three things: 'Climate change kills X people per year', 'Lithium mining uses enormous water', 'Cobalt mining sometimes involves child labour'. In small groups, students discuss: 'How should governments and companies balance these concerns when making decisions about batteries?' Each group shares their thinking.
Example: In Mrs Diallo's class, students realised the trade-offs were genuinely hard. The teacher said: 'You have just done the kind of work that real climate policy involves. There are no easy answers. The transition must happen — climate change is the larger threat. But the costs of getting there are real and need to be addressed. The lithium battery story is one of the clearest cases of this complexity. The same kind of trade-off thinking applies to many other environmental decisions.'
Innovation Across Countries
Instructions: On the board, list the three Nobel laureates and their countries: Whittingham (UK), Goodenough (US/UK), Yoshino (Japan). Then add: lithium produced in Chile, Bolivia, Argentina, Australia. Cobalt mostly from DRC. Batteries manufactured mostly in China, South Korea, Japan. In small groups, students discuss: how does this geographic spread shape the technology and its impact?
Example: In one class, students realised that no single country could produce lithium batteries alone. The teacher said: 'You have just understood something important about modern technology. It is genuinely global. Innovation happens in many places. Production happens in others. Raw materials come from yet others. Profits and benefits are distributed unevenly. The lithium battery is a particularly clear example. The same pattern applies to most modern technologies. Understanding the geography is part of understanding the ethics.'
Where to go next
  • Try a lesson on the solar lantern for the technology that often pairs with lithium batteries in rural areas.
  • Try a lesson on the desalination membrane for another modern technology with both promises and challenges.
  • Try a lesson on the reusable bag for another object central to environmental decision-making.
  • Connect this lesson to science class with a longer project on battery chemistry. The technology is real chemistry, accessible to interested students.
  • Connect this lesson to citizenship class with a longer discussion of supply chain ethics. The lithium-cobalt-battery chain is one specific example of a broader pattern.
  • Connect this lesson to history class with a longer project on the energy transition. The lithium battery is one of many technologies enabling this historical shift.
Key takeaways
  • The lithium-ion battery stores energy by moving lithium ions between two electrodes through a liquid electrolyte. It is the dominant rechargeable battery technology in modern use.
  • The technology was developed by John Goodenough, M. Stanley Whittingham, and Akira Yoshino in the 1970s and 1980s. The first commercial product was sold by Sony in 1991. The three shared the 2019 Nobel Prize in Chemistry.
  • Lithium batteries power smartphones, laptops, electric vehicles, electric tools, and grid-scale energy storage. They are essential to the energy transition away from fossil fuels.
  • Battery prices have fallen about 90% since 2010, making electric vehicles cost-competitive with petrol cars. Global production capacity is over 2,000 GWh annually.
  • The technology raises serious supply chain concerns. Lithium mining in the Atacama Desert (Chile) uses enormous amounts of water. Cobalt mining in the Democratic Republic of the Congo sometimes involves child labour. Battery recycling is currently underdeveloped.
  • Better practices are emerging: lithium iron phosphate (LFP) batteries contain no cobalt; recycling is improving; alternative chemistries (sodium-ion, solid-state) are being developed. The work of making the energy transition truly sustainable continues.
Sources
  • The Lithium-Ion Battery: A Brief History — Royal Society of Chemistry (2019) [academic]
  • Cobalt Red: How the Blood of the Congo Powers Our Lives — Siddharth Kara (2023) [book]
  • How lithium mining is impacting Chile — BBC News (2022) [news]
  • Battery Storage and Renewable Energy Markets — International Energy Agency (2024) [institution]
  • Nobel Prize in Chemistry 2019 — Nobel Foundation (2019) [institution]