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News Release 11-033

Iceland Volcano's Molten Rock Could Become Source of High-Grade Energy

Krafla volcano gives geologists unique, unexpected opportunity to study magma

Photo taken at night of incandescent lava flowing downslope from a vent at Iceland's Krafla volcano.

An incandescent lava flow winds its way downslope from a vent at Iceland's Krafla volcano.


February 16, 2011

This material is available primarily for archival purposes. Telephone numbers or other contact information may be out of date; please see current contact information at media contacts.

Geologists drilling an exploratory geothermal well in 2009 in the Krafla volcano in Iceland met with a big surprise: underground lava, also called magma, flowed into the well at 2.1 kilometers (6,900 feet) depth.

It forced the scientists to stop drilling.

"To the best of our knowledge, only one previous instance has been documented of magma flowing into a geothermal well while drilling," said Wilfred Elders, a geologist at the University of California, Riverside, who led the research team.

The scientists received $3.5 million from the National Science Foundation (NSF), and $1.5 million from the International Continental Scientific Drilling Program, to conduct their research.

Elders and his team studied the well within the Krafla caldera as part of the Iceland Deep Drilling Project, an industry-government consortium, to test whether geothermal fluids at supercritical pressures and temperatures could be exploited as sources of power, said Leonard Johnson, program director in NSF's Division of Earth Sciences, which funded the research.

"We were drilling a well designed to search for very deep--4.5 kilometers (15,000 feet)--geothermal resources in the volcano," said Elders.

"While the magma flow interrupted our project, it gave us a unique opportunity to test a very hot geothermal system as an energy source."

Currently, a third of the electric power and 95 percent of home heating in Iceland is produced from steam and hot water that occurs naturally in volcanic rocks.

"The economics of generating electric power from such geothermal steam improves the higher its temperature and pressure," Elders said. 

"As you drill deeper into a hot zone, the temperature and pressure rise. It should be possible to reach an environment where a denser fluid with very high heat content--but also with unusually low viscosity occurs--so-called 'supercritical water.'"

Although such supercritical water is used in large coal-fired electric power plants, he said, "no one had tried to use the supercritical water that should occur naturally in the deeper zones of geothermal areas."

Elders and colleagues report in the March issue of the journal GEOLOGY, published by the Geological Society of America, that although the Krafla volcano, like other volcanoes in Iceland, is basaltic (a volcanic rock containing 45-50 percent silica), the magma they encountered is a rhyolite (a volcanic rock containing 65-70 percent silica).

"Our analyses show that this magma formed by partial melting of basalts within the Krafla volcano," Elders said.

"The occurrence of minor amounts of rhyolite in some basalt volcanoes has always been something of a puzzle.

"It had been inferred that some unknown process in the source area of magmas, in the mantle deep below the crust of the Earth, allows a silica-rich rhyolite melt to form--in addition to the dominant silica-poor basalt magma."

Elders said that in geothermal systems water reacts with and alters the composition of the rocks, a process termed "hydrothermal alteration."

"Our research shows that the rhyolite formed when a mantle-derived basaltic magma encountered hydrothermally altered basalt, and partially melted and assimilated that rock," he said.

In the spring of 2009, Elders and colleagues progressed normally with drilling the well to 2 kilometers (6,600 feet) depth.

In the next 100 meters (330 feet), however, multiple acute drilling problems occurred.

The drillers determined that at 2,104 meters (6,900 feet) depth, the rate of penetration suddenly increased and the torque on the drilling assembly increased, halting its rotation.

When the drill string was pulled up more than 10 meters (33 feet) and lowered again, the drill bit became stuck at 2,095 meters (6,875 feet).

An intrusion of magma had filled the lowest 9 meters (30 feet) of the open borehole. The team terminated the drilling and completed the hole as a production well.

"When the well was tested high pressure dry steam flowed to the surface with a temperature of 400 degrees Celsius or 750 degrees Fahrenheit, coming from a depth shallower than the magma," Elders said.

He and colleagues estimated that this steam could generate 25 megawatts of electricity if passed through a suitable turbine--enough electricity to power 25,000 to 30,000 homes.

"What makes this well an attractive source of energy," said Elders, "is that typical high-temperature geothermal wells produce only 5 to 8 megawatts of electricity from 300 degrees Celsius or 570 degrees Fahrenheit wet steam."

He believes it should be possible to find reasonably shallow bodies of magma, elsewhere in Iceland and the world, wherever young volcanic rocks occur.

"In the future these could become attractive sources of high-grade energy," said Elders.

The Iceland Deep Drilling Project has not abandoned the search for supercritical geothermal resources. The project plans to drill a second deep hole in southwest Iceland in 2013.

Elders was joined in the research project by scientists at HS Orka hf (HS Power Co.), Iceland; University of California, Davis; Stanford University; Iceland GeoSurvey; Landsvirkjun Power, Iceland; U.S. Geological Survey; New Mexico Institute of Mining and Technology; and the University of Oregon, Eugene

-NSF-

Media Contacts
Cheryl Dybas, NSF, (703) 292-7734, email: cdybas@nsf.gov
Iqbal Pittalwala, UC-Riverside, (951) 827-6050, email: iqbal@ucr.edu
Christa Stratton, Geological Society of America, (303) 357-1093, email: cstratton@geosociety.org

The U.S. National Science Foundation propels the nation forward by advancing fundamental research in all fields of science and engineering. NSF supports research and people by providing facilities, instruments and funding to support their ingenuity and sustain the U.S. as a global leader in research and innovation. With a fiscal year 2023 budget of $9.5 billion, NSF funds reach all 50 states through grants to nearly 2,000 colleges, universities and institutions. Each year, NSF receives more than 40,000 competitive proposals and makes about 11,000 new awards. Those awards include support for cooperative research with industry, Arctic and Antarctic research and operations, and U.S. participation in international scientific efforts.

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