Could We Use Volcanoes To Make Electricity?

Turning red-hot lava from an active volcano into electricity would be dangerous and unreliable. But many countries, including the U.S., have found ways to tap volcanic heat to make electricity.

84c9ded3-13e0-4988-80b8-f57ba07f697bHiResProxy
Lava spatters from a vent at Kilauea in Hawaii during an eruption in September 2023. M. Patrick, USGS, via NPS, CC BY-ND

Newsletter

Sign up for our email newsletter for the latest science news
 

Turning red-hot lava from an active volcano into electricity would be dangerous and unreliable. Volcanoes don’t erupt on predictable schedules, and lava cools too quickly. But many countries, including the U.S., have found ways to tap volcanic heat to make electricity.

Geothermal energy comes from heat generated by natural processes deep within the Earth. In most areas, this heat only warms rocks and underground water near the surface. In volcanically active regions, however, the heat is much more intense. Sometimes, it melts rock, forming magma.

Volcanoes act like giant heat vents, raising magma closer to Earth’s surface. Some of this molten rock may erupt, but much of it remains underground, heating the surrounding rocks and water. Where heated water rises to the surface, it creates hot springs and geysers that can last for thousands of years.

To harness this energy to generate electricity, engineers identify areas where magma is near the surface and drill deep wells down to the heated rocks and water. These wells bring steam to the surface, where it is directed into a power plant to spin turbines and generate electricity.

Earth’s heat can be converted into geothermal energy in several different ways.


After it produces electricity, the steam cools and condenses back into hot water. The water may be used to convert a different liquid with a much lower boiling point, such as butane, to drive a second generator. Then, it is pumped back underground to be reheated.

The Earth constantly produces heat, so geothermal energy is a renewable resource. And geothermal power plants produce much less pollution, waste, and greenhouse gas emissions that warm Earth’s climate than burning coal, gas, oil, or using nuclear energy.

Geothermal energy sources can last for decades or even longer. Unlike other renewable sources such as solar and wind power, geothermal energy is available 24/7, 365 days a year.

The World’s Geothermal Hot Spots

Geothermal energy is already used in many places around the world, especially in regions with a lot of volcanic activity. For example, almost all of Iceland’s electricity comes from renewable sources, with geothermal energy supplying about 25%. The country sits on top of many active volcanoes, making it a perfect place for geothermal power plants.

Some U.S. states, including Californiaand Nevada, have geothermal power plants, thanks to their volcanic regions. Other active geothermal sites, such as Yellowstone National Park in Wyoming, are protected from development.

Most geothermal power plants in the United States are in western states and Hawaii, where geothermal energy resources are close to the Earth’s surface. USEIA

Challenges for Geothermal Power

Why isn’t geothermal energy used as widely as wind or solar power? First, geothermal power plants need to be near volcanoes or other places where it is unusually hot beneath the surface. These resources aren’t always near large cities or industries that use a lot of electricity.

Second, drilling deep wells and building power plants can be expensive. However, the long-term benefits of geothermal power often outweigh the initial costs.

Third, in some cases, drilling and pumping water under pressure can cause small earthquakes. Scientists and engineers are working to predict and manage this effect.

Despite these challenges, tapping into the Earth’s natural heat can create a renewable, reliable and clean source of energy. As technology improves, more places around the world will turn to geothermal energy to light up people’s lives. Volcanoes are reminders of a great powerhouse deep underground that’s waiting to be harnessed.


David Kitchen is an Associate Professor of Geology at the University of Richmond. This article is republished from The Conversation under a Creative Commons license. Read the original article.

1 free article left
Want More? Get unlimited access for as low as $1.99/month

Already a subscriber?

Register or Log In

1 free articleSubscribe
Discover Magazine Logo
Want more?

Keep reading for as low as $1.99!

Subscribe

Already a subscriber?

Register or Log In

More From Discover
Recommendations From Our Store
Stay Curious
Join
Our List

Sign up for our weekly science updates.

 
Subscribe
To The Magazine

Save up to 40% off the cover price when you subscribe to Discover magazine.

Copyright © 2024 LabX Media Group