0% of global electricity is generated from Geothermal
Geothermal energy harnesses the heat that originates from the Earth's interior to generate electricity. This energy form capitalizes on the natural thermal energy stored beneath the Earth's crust, which is a result of both the original formation of the planet and ongoing radioactive decay in specific minerals. Geothermal power plants convert the warmth from underground reservoirs of steam and hot water into clean energy, making it a sustainable and reliable electricity source with minimal environmental impact.
The process of generating electricity from geothermal energy involves several key steps. Water or steam from underground reservoirs is piped up to the surface, usually in regions with volcanic or tectonic activity. This steam drives the turbines connected to generators that produce electricity. Afterward, the steam or cooled water is injected back into the Earth to be reheated, ensuring a sustainable cycle of energy extraction. There are various types of geothermal power plants, including dry steam, flash steam, and binary cycle plants, each suited to specific geothermal conditions.
A major advantage of geothermal energy is its low carbon intensity, with emissions around 38 gCO2eq/kWh. This is significantly lower than traditional fossil fuels like coal and oil, which produce 820 and 650 gCO2eq/kWh respectively. Low-carbon technologies play a crucial role in mitigating climate change and reducing air pollution, and geothermal energy stands as a vital component alongside other clean sources like wind, nuclear, and solar. Wind and solar energy, for instance, emit 11 and 45 gCO2eq/kWh respectively, highlighting a collective need to transition towards these sustainable options.
Geothermal energy contributes to global electricity generation, currently producing about 0.46% of the electricity consumed worldwide. While this might seem a small fraction, it shows promise when considering the concentrated use in specific regions. For example, Iceland utilizes its geothermal resources to generate nearly 28% of its electricity, reflecting the country's commitment to low-carbon energy. Similarly, New Zealand, with its abundant volcanic activity, generates 22% of its electricity from geothermal sources, driving sustainability in its energy mix.
This form of energy also plays a notable role in certain regions within the United States. Nevada, known for its geothermal potential, draws 8% of its electricity from geothermal sources. Similarly, California, a leader in clean energy initiatives, sources 4% of its electricity from geothermal plants. Other countries like Costa Rica also demonstrate the practicability of geothermal energy, with 11% of their electricity stemming from this green resource. These examples highlight the positive impact geothermal energy can have within diverse geographical contexts, reinforcing the expansion of low-carbon solutions worldwide.
Given the pressing challenges of climate change and the need for sustainable growth in electricity demand worldwide, maximizing the potential of low-carbon energy sources is more crucial than ever. Alongside geothermal energy, wind, nuclear, and solar power offer critical pathways towards a greener future. Nuclear energy, with its minimal 12 gCO2eq/kWh emission rate, and solar power, known for its scalability and accessibility, represent essential components in the global energy transition. Together, these clean energy sources can help achieve a sustainable balance between meeting electricity demands and preserving the environment for future generations.
| Country/Region | kWh/person | % | TWh |
|---|---|---|---|
| Iceland | 12963.8 W | 27.7% | 5.2 TWh |
| New Zealand | 1754.0 W | 21.6% | 9.2 TWh |
| Nevada | 1179.3 W | 8.2% | 3.9 TWh |
| Costa Rica | 279.1 W | 11.0% | 1.4 TWh |
| California | 272.8 W | 3.6% | 10.7 TWh |
| Guadeloupe | 260.0 W | 6.1% | 0.1 TWh |
| Hawaii | 179.3 W | 2.2% | 0.3 TWh |
| Utah | 132.6 W | 1.2% | 0.5 TWh |
| El Salvador | 118.1 W | 17.7% | 0.8 TWh |
| Kenya | 104.6 W | 40.3% | 6.0 TWh |
| Nicaragua | 101.1 W | 12.5% | 0.7 TWh |
| Turkey | 97.8 W | 2.6% | 8.6 TWh |
| Italy | 87.9 W | 1.6% | 5.2 TWh |
| Philippines | 80.6 W | 7.9% | 9.4 TWh |
| Indonesia | 60.2 W | 4.8% | 16.9 TWh |
| United States | 45.5 W | 0.3% | 15.8 TWh |
| Oregon | 43.0 W | 0.3% | 0.2 TWh |
| Honduras | 32.9 W | 2.9% | 0.3 TWh |
| New Mexico | 31.5 W | 0.2% | 0.1 TWh |
| Martinique | 28.6 W | 0.7% | 0.0 TWh |
| Idaho | 26.5 W | 0.2% | 0.1 TWh |
| Japan | 26.0 W | 0.3% | 3.2 TWh |
| Mexico | 23.0 W | 0.8% | 3.0 TWh |
| Guatemala | 18.8 W | 2.4% | 0.3 TWh |
| Czechia | 18.4 W | 0.3% | 0.2 TWh |
| The World | 17.4 W | 0.5% | 143.3 TWh |
| EU | 14.4 W | 0.2% | 6.5 TWh |
| Portugal | 13.0 W | 0.2% | 0.1 TWh |
| Papua New Guinea | 9.6 W | 2.1% | 0.1 TWh |
| Netherlands | 8.7 W | 0.1% | 0.2 TWh |
| Slovakia | 7.2 W | 0.1% | 0.0 TWh |
| Norway | 7.2 W | 0.0% | 0.0 TWh |
| Germany | 5.8 W | 0.1% | 0.5 TWh |
| Chile | 5.6 W | 0.1% | 0.1 TWh |
| Finland | 5.3 W | 0.0% | 0.0 TWh |
| Croatia | 5.2 W | 0.1% | 0.0 TWh |
| Sub-Saharan Africa | 4.7 W | 1.1% | 5.8 TWh |
| South Africa | 4.1 W | 0.1% | 0.3 TWh |
| France | 1.6 W | 0.0% | 0.1 TWh |
| South Korea | 1.5 W | 0.0% | 0.1 TWh |
| Poland | 1.3 W | 0.0% | 0.1 TWh |
| Hungary | 1.2 W | 0.0% | 0.0 TWh |
| Republic of China (Taiwan) | 1.1 W | 0.0% | 0.0 TWh |
| Spain | 1.0 W | 0.0% | 0.1 TWh |
| Ethiopia | 0.2 W | 0.2% | 0.0 TWh |
| India | 0.2 W | 0.0% | 0.3 TWh |
| Austria | 0.0 W | 0.0% | 0.0 TWh |








