Electrification
Mapped: Solar Power by Country in 2021
Mapped: Solar Power by Country in 2021
The world is adopting renewable energy at an unprecedented pace, and solar power is leading the way.
Despite a 4.5% fall in global energy demand in 2020, renewable energy technologies showed promising progress. While the growth in renewables was strong across the board, solar power led from the front with 127 gigawatts installed in 2020, its largest-ever annual capacity expansion.
The above infographic uses data from the International Renewable Energy Agency (IRENA) to map solar power capacity by country in 2021. This includes both solar photovoltaic (PV) and concentrated solar power capacity.
The Solar Power Leaderboard
From the Americas to Oceania, countries in virtually every continent (except Antarctica) added more solar to their mix last year. Here’s a snapshot of solar power capacity by country at the beginning of 2021:
Country | Installed capacity, megawatts | Watts* per capita | % of world total |
---|---|---|---|
China 🇨🇳 | 254,355 | 147 | 35.6% |
U.S. 🇺🇸 | 75,572 | 231 | 10.6% |
Japan 🇯🇵 | 67,000 | 498 | 9.4% |
Germany 🇩🇪 | 53,783 | 593 | 7.5% |
India 🇮🇳 | 39,211 | 32 | 5.5% |
Italy 🇮🇹 | 21,600 | 345 | 3.0% |
Australia 🇦🇺 | 17,627 | 637 | 2.5% |
Vietnam 🇻🇳 | 16,504 | 60 | 2.3% |
South Korea 🇰🇷 | 14,575 | 217 | 2.0% |
Spain 🇪🇸 | 14,089 | 186 | 2.0% |
United Kingdom 🇬🇧 | 13,563 | 200 | 1.9% |
France 🇫🇷 | 11,733 | 148 | 1.6% |
Netherlands 🇳🇱 | 10,213 | 396 | 1.4% |
Brazil 🇧🇷 | 7,881 | 22 | 1.1% |
Turkey 🇹🇷 | 6,668 | 73 | 0.9% |
South Africa 🇿🇦 | 5,990 | 44 | 0.8% |
Taiwan 🇹🇼 | 5,817 | 172 | 0.8% |
Belgium 🇧🇪 | 5,646 | 394 | 0.8% |
Mexico 🇲🇽 | 5,644 | 35 | 0.8% |
Ukraine 🇺🇦 | 5,360 | 114 | 0.8% |
Poland 🇵🇱 | 3,936 | 34 | 0.6% |
Canada 🇨🇦 | 3,325 | 88 | 0.5% |
Greece 🇬🇷 | 3,247 | 258 | 0.5% |
Chile 🇨🇱 | 3,205 | 142 | 0.4% |
Switzerland 🇨🇭 | 3,118 | 295 | 0.4% |
Thailand 🇹🇭 | 2,988 | 43 | 0.4% |
United Arab Emirates 🇦🇪 | 2,539 | 185 | 0.4% |
Austria 🇦🇹 | 2,220 | 178 | 0.3% |
Czech Republic 🇨🇿 | 2,073 | 194 | 0.3% |
Hungary 🇭🇺 | 1,953 | 131 | 0.3% |
Egypt 🇪🇬 | 1,694 | 17 | 0.2% |
Malaysia 🇲🇾 | 1,493 | 28 | 0.2% |
Israel 🇮🇱 | 1,439 | 134 | 0.2% |
Russia 🇷🇺 | 1,428 | 7 | 0.2% |
Sweden 🇸🇪 | 1,417 | 63 | 0.2% |
Romania 🇷🇴 | 1,387 | 71 | 0.2% |
Jordan 🇯🇴 | 1,359 | 100 | 0.2% |
Denmark 🇩🇰 | 1,300 | 186 | 0.2% |
Bulgaria 🇧🇬 | 1,073 | 152 | 0.2% |
Philippines 🇵🇭 | 1,048 | 9 | 0.1% |
Portugal 🇵🇹 | 1,025 | 81 | 0.1% |
Argentina 🇦🇷 | 764 | 17 | 0.1% |
Pakistan 🇵🇰 | 737 | 6 | 0.1% |
Morocco 🇲🇦 | 734 | 6 | 0.1% |
Slovakia 🇸🇰 | 593 | 87 | 0.1% |
Honduras 🇭🇳 | 514 | 53 | 0.1% |
Algeria 🇩🇿 | 448 | 10 | 0.1% |
El Salvador 🇸🇻 | 429 | 66 | 0.1% |
Iran 🇮🇷 | 414 | 5 | 0.1% |
Saudi Arabia 🇸🇦 | 409 | 12 | 0.1% |
Finland 🇫🇮 | 391 | 39 | 0.1% |
Dominican Republic 🇩🇴 | 370 | 34 | 0.1% |
Peru 🇵🇪 | 331 | 10 | 0.05% |
Singapore 🇸🇬 | 329 | 45 | 0.05% |
Bangladesh 🇧🇩 | 301 | 2 | 0.04% |
Slovenia 🇸🇮 | 267 | 128 | 0.04% |
Uruguay 🇺🇾 | 256 | 74 | 0.04% |
Yemen 🇾🇪 | 253 | 8 | 0.04% |
Iraq 🇮🇶 | 216 | 5 | 0.03% |
Cambodia 🇰🇭 | 208 | 12 | 0.03% |
Cyprus 🇨🇾 | 200 | 147 | 0.03% |
Panama 🇵🇦 | 198 | 46 | 0.03% |
Luxembourg 🇱🇺 | 195 | 244 | 0.03% |
Malta 🇲🇹 | 184 | 312 | 0.03% |
Indonesia 🇮🇩 | 172 | 1 | 0.02% |
Cuba 🇨🇺 | 163 | 14 | 0.02% |
Belarus 🇧🇾 | 159 | 17 | 0.02% |
Senegal 🇸🇳 | 155 | 8 | 0.02% |
Norway 🇳🇴 | 152 | 17 | 0.02% |
Lithuania 🇱🇹 | 148 | 37 | 0.02% |
Namibia 🇳🇦 | 145 | 55 | 0.02% |
New Zealand 🇳🇿 | 142 | 29 | 0.02% |
Estonia 🇪🇪 | 130 | 98 | 0.02% |
Bolivia 🇧🇴 | 120 | 10 | 0.02% |
Oman 🇴🇲 | 109 | 21 | 0.02% |
Colombia 🇨🇴 | 107 | 2 | 0.01% |
Kenya 🇰🇪 | 106 | 2 | 0.01% |
Guatemala 🇬🇹 | 101 | 6 | 0.01% |
Croatia 🇭🇷 | 85 | 17 | 0.01% |
World total 🌎 | 713,970 | 83 | 100.0% |
*1 megawatt = 1,000,000 watts.
China is the undisputed leader in solar installations, with over 35% of global capacity. What’s more, the country is showing no signs of slowing down. It has the world’s largest wind and solar project in the pipeline, which could add another 400,000MW to its clean energy capacity.
Following China from afar is the U.S., which recently surpassed 100,000MW of solar power capacity after installing another 50,000MW in the first three months of 2021. Annual solar growth in the U.S. has averaged an impressive 42% over the last decade. Policies like the solar investment tax credit, which offers a 26% tax credit on residential and commercial solar systems, have helped propel the industry forward.
Although Australia hosts a fraction of China’s solar capacity, it tops the per capita rankings due to its relatively low population of 26 million people. The Australian continent receives the highest amount of solar radiation of any continent, and over 30% of Australian households now have rooftop solar PV systems.
China: The Solar Champion
In 2020, President Xi Jinping stated that China aims to be carbon neutral by 2060, and the country is taking steps to get there.
China is a leader in the solar industry, and it seems to have cracked the code for the entire solar supply chain. In 2019, Chinese firms produced 66% of the world’s polysilicon, the initial building block of silicon-based photovoltaic (PV) panels. Furthermore, more than three-quarters of solar cells came from China, along with 72% of the world’s PV panels.
With that said, it’s no surprise that 5 of the world’s 10 largest solar parks are in China, and it will likely continue to build more as it transitions to carbon neutrality.
What’s Driving the Rush for Solar Power?
The energy transition is a major factor in the rise of renewables, but solar’s growth is partly due to how cheap it has become over time. Solar energy costs have fallen exponentially over the last decade, and it’s now the cheapest source of new energy generation.
Since 2010, the cost of solar power has seen a 85% decrease, down from $0.28 to $0.04 per kWh. According to MIT researchers, economies of scale have been the single-largest factor in continuing the cost decline for the last decade. In other words, as the world installed and made more solar panels, production became cheaper and more efficient.
This year, solar costs are rising due to supply chain issues, but the rise is likely to be temporary as bottlenecks resolve.
Electrification
Visualizing the Supply Deficit of Battery Minerals (2024-2034P)
A surplus of key metals is expected to shift to a major deficit within a decade.
Visualizing the Supply Deficit of Battery Minerals (2024-2034P)
The world currently produces a surplus of key battery minerals, but this is projected to shift to a significant deficit over the next 10 years.
This graphic illustrates this change, driven primarily by growing battery demand. The data comes exclusively from Benchmark Mineral Intelligence, as of November 2024.
Minerals in a Lithium-Ion Battery Cathode
Minerals make up the bulk of materials used to produce parts within the cell, ensuring the flow of electrical current:
- Lithium: Acts as the primary charge carrier, enabling energy storage and transfer within the battery.
- Cobalt: Stabilizes the cathode structure, improving battery lifespan and performance.
- Nickel: Boosts energy density, allowing batteries to store more energy.
- Manganese: Enhances thermal stability and safety, reducing overheating risks.
The cells in an average battery with a 60 kilowatt-hour (kWh) capacity—the same size used in a Chevy Bolt—contain roughly 185 kilograms of minerals.
Battery Demand Forecast
Due to the growing demand for these materials, their production and mining have increased exponentially in recent years, led by China. In this scenario, all the metals shown in the graphic currently experience a surplus.
In the long term, however, with the greater adoption of batteries and other renewable energy technologies, projections indicate that all these minerals will enter a deficit.
For example, lithium demand is expected to more than triple by 2034, resulting in a projected deficit of 572,000 tonnes of lithium carbonate equivalent (LCE). According to Benchmark analysis, the lithium industry would need over $40 billion in investment to meet demand by 2030.
Metric | Lithium (in tonnes LCE) | Nickel (in tonnes) | Cobalt (in tonnes) | Manganese (in tonnes) |
---|---|---|---|---|
2024 Demand | 1,103,000 | 3,440,000 | 230,000 | 119,000 |
2024 Surplus | 88,000 | 117,000 | 24,000 | 11,000 |
2034 Demand | 3,758,000 | 6,082,000 | 468,000 | 650,000 |
2034 Deficit | -572,000 | -839,000 | -91,000 | -307,000 |
Nickel demand, on the other hand, is expected to almost double, leading to a deficit of 839,000 tonnes by 2034. The surge in demand is attributed primarily to the rise of mid- and high-performance electric vehicles (EVs) in Western markets.
Electrification
Visualizing the EU’s Critical Minerals Gap by 2030
This graphic underscores the scale of the challenge the bloc faces in strengthening its critical mineral supply by 2030.
Visualizing EU’s Critical Minerals Gap by 2030
The European Union’s Critical Raw Material Act sets out several ambitious goals to enhance the resilience of its critical mineral supply chains.
The Act includes non-binding targets for the EU to build sufficient mining capacity so that mines within the bloc can meet 10% of its critical mineral demand.
Additionally, the Act establishes a goal for 40% of demand to be met by processing within the bloc, and 25% through recycling.
Several months after the Act’s passage in May 2024, this graphic highlights the scale of the challenge the EU aims to overcome. This data comes exclusively from Benchmark Mineral Intelligence, as of July 2024. The graphic excludes synthetic graphite.
Securing Europe’s Supply of Critical Materials
With the exception of nickel mining, none of the battery minerals deemed strategic by the EU are on track to meet these goals.
Graphite, the largest mineral component used in batteries, is of particular concern. There is no EU-mined supply of manganese ore or coke, the precursor to synthetic graphite.
By 2030, the European Union is expected to supply 16,000 tonnes of flake graphite locally, compared to the 45,000 tonnes it would need to meet the 10% mining target.
Metal | 2030 Demand (tonnes) | Mining (F) | Processing (F) | Recycling (F) | Mining Target | Processing Target | Recycling Target |
---|---|---|---|---|---|---|---|
Lithium | 459K | 29K | 46K | 25K | 46K | 184K | 115K |
Nickel | 403K | 42K | 123K | 25K | 40K | 161K | 101K |
Cobalt | 94K | 1K | 19K | 6K | 9K | 37K | 23K |
Manganese | 147K | 0K | 21K | 5K | 15K | 59K | 37K |
Flake Graphite | 453K | 16K | 17K | N/A | 45K | 86K | N/A |
The EU is also expected to mine 29,000 tonnes of LCE (lithium carbonate equivalent) compared to the 46,000 tonnes needed to meet the 10% target.
In terms of mineral processing, the bloc is expected to process 25% of its lithium requirements, 76% of nickel, 51% of cobalt, 36% of manganese, and 20% of flake graphite.
The EU is expected to recycle only 22% of its lithium needs, 25% of nickel, 26% of cobalt, and 14% of manganese. Graphite, meanwhile, is not widely recycled on a commercial scale.
-
Electrification3 years ago
The Key Minerals in an EV Battery
-
Energy Shift3 years ago
What Are the Five Major Types of Renewable Energy?
-
Electrification2 years ago
The Six Major Types of Lithium-ion Batteries: A Visual Comparison
-
Real Assets2 years ago
Which Countries Have the Lowest Inflation?
-
Misc2 years ago
How Is Aluminum Made?
-
Electrification3 years ago
EVs vs. Gas Vehicles: What Are Cars Made Out Of?
-
Electrification2 years ago
The World’s Top 10 Lithium Mining Companies
-
Real Assets1 year ago
200 Years of Global Gold Production, by Country