Iceland’s volcano eruptions may last decades, researchers find

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Iceland’s volcano eruptions may last decades, researchers find

The island is just beginning a long, disruptive volcanic episode near Iceland’s capital 

Iceland’s ongoing volcanic eruptions may continue on and off for years to decades, threatening the country’s most densely populated region and vital infrastructure, researchers predict from local earthquake and geochemical data. 

Aerial map of grindavik showing the location of the Infrared siganture, Defensive walls, and Power plant
An active volcanic fissure in Iceland near the town of Grindavík, power plants and the world-famous Blue Lagoon spa in spring 2024. Image by Lauren Dauphin/NASA 2Earth Observatory. 

The eruptions on the Reykjanes Peninsula have forced authorities to declare a state of emergency, with a series of eight eruptions having occurred since 2021. This southwestern region is home to 70 percent of the country’s population, its only international airport, and several geothermal power plants that supply hot water and electricity. The most recent eruption in May through June triggered the evacuation of residents and visitors of the Blue Lagoon geothermal spa, a popular tourist attraction, for the third time in more than two months.

Although Iceland sees regular eruptions because it sits above a volcanic hot spot, the Reykjanes Peninsula has been dormant for 800 years. Its last volcanic era continued over centuries however, prompting scientists to predict the renewed volcanism to be the start of a long episode. 

Under an hour’s drive from the island’s capital city Reykjavík, the eruptions pose considerable risks for economic disruption, and they leave evacuated communities uncertain of a possible return.

An international team of scientists has been watching the volcanoes over the past three years. Analyzing seismic tomography imaging and the composition of lava samples, they’ve uncovered parts of the geological processes behind the new volcanic era. They predict the region may have to prepare for recurring eruptions lasting years to decades and possibly centuries. 

The researchers report their findings in a paper published June 26 in the journal Terra Nova. The project included collaborations from the University of Oregon, Uppsala University in Sweden, University of Iceland, Czech Academy of Sciences and University of California, San Diego. The work follows an earlier Nature Communications study of the initial Reykjanes eruptions in 2021.

Scientists check equipment near an active volcano eruption
Initial state of the volcano eruption, smoke lightly pouring out of the caldera
The volcano pours lava out of the caldera
Volcano fully erupting with large flows of lava

(Top Photo) Scientists collecting volcanic rock during the July 2023 Fagradalsfjall eruption.
(Bottom Photos) The progression of the 2021 Fagradalsfjall eruption. 

Almost all of Iceland’s island is built from lava, said Ilya Bindeman, a volcanologist and earth sciences professor at the UO. The country sits on the Mid-Atlantic Ridge, the tectonic plate boundary that causes North America and Eurasia to push further apart. The drifting of these plates can spark volcanic eruptions when hot rock from the earth’s mantle — the middle and largest layer of the planet — melts and rises to the surface.

Although scientists know the origin of Reykjanes Peninsula’s current eruptions is plate movement, the kind of magma storage and plumbing systems that feed them are unidentified, Bindeman said. The peninsula consists of eight volcanically active sites, so understanding whether there is one shared magma source or multiple independent ones and their depth can help predict the duration and impact of these eruptions.

Using geochemical and seismic data, the researchers investigated whether the magma of the initial eruptions from one volcano in the peninsula from 2021 to 2023 came from the same source as the magma in the recent eruptions of a different volcano to the west. 

Bindeman specializes in isotopic analysis, which can help identify the “fingerprint” of magma. (See Focus on Equipment and Methodology below.) The unique combination of trace elements can help differentiate one magma source from another.

Beaker of volcanic sample being poured into dish
A sample of volcanic rock being prepared for analysis. 
Ilya Bindeman
Ilya Bindeman is a volcanologist at the University of Oregon who has been studying the ongoing eruptions in Iceland.
Lava stretches across a road, leaving debris behind
A wall of lava lies across a road

Lava from the January 2024 Sundhnúkur eruption reaching the outskirts of the town of Grindavik. Photographed in April 2024.

Analyzing samples of lava rock from two different volcanoes in the peninsula, their similar fingerprints implied a shared magma storage zone below the peninsula. Imaging of earth’s interior based on local earthquakes also suggested the existence of a reservoir about 5.5 to 7.5 miles in the earth’s crust, the shallowest layer.

Although this marks the beginning of potentially persistent volcanic episodes in Iceland, the researchers can’t precisely predict yet how long the episodes and the gaps between each will last.

“Nature is never regular,” Bindeman said. “We don't know how long and how frequently it will continue for the next ten or even hundred years. A pattern will emerge, but nature always has exceptions and irregularities.”

Discussions are continuing on plans to safely drill into the volcanic sites to glean insights into the geological processes driving the eruptions. 

Because the volcanic activity is less volatile and explosive than eruptions in other countries, it provides a rare opportunity for scientists to approach fissures actively erupting lava, Bindeman said. He called it a “natural laboratory” both astonishing and chilling.

“When you witness a volcanic eruption, you can feel that these are the massive forces of nature, and you yourself are very small,” Bindeman said. “These events are ordinary from the geological scale, but from the human scale, they can be devastating.”

Scientist stands near cooling lava

— Story by Leila Okahata
— Volcano photos and videos courtesy of Valentin Troll, Uppsala University
— Lab photos and videos by Charlie Litchfield and Nicolas Walcott
— Layout design by Tim Beltran and Paul Kozik


Focus on Equipment and Methodology

A laser flourination line

Scientists can measure the abundance of isotopes, elements with the same chemical property but different masses, in magma to identify its "fingerprint". There are three different isotopes of oxygen, for example.

“In the air we breathe, there's a mixture of these oxygen isotopes and we don't feel the difference,” Bindeman said. “Their differences are usually not important for chemical reactions but are important to recognize as their relative abundances in magma can differentiate one magma source from another.”

Using an apparatus called a laser fluorination line, scientists can extract and measure the oxygen isotopes in minerals. The unique abundance of oxygen isotopes can serve as identification between different magma sources.