Computer models show how deep carbon could return to Earth’s surface


Share post:

Computer simulations of water under extreme pressure are helping geochemists understand how carbon might be recycled from hundreds of miles below Earth’s surface.

Computer models show how deep carbon could return to Earth's surface
This rendering shows a carbonate ion (red/grey) dissolved in water (pink/white) against a backdrop of a cross section of the Earth. New computer simulations show that under pressure deep in the Earth, carbonate could dissolve in water, providing a route for carbon to return to the Earth’s surface [Credit: Ding Pan and Yubo Zhang/UC Davis rendering]

The work, by researchers at the University of California, Davis, and Johns Hopkins University, is published March 18 in the journal Proceedings of the National Academy of Sciences.

Carbon compounds are the basis of life, provide most of our fuels and contribute to climate change. The cycling of carbon through the oceans, atmosphere and shallow crust of Earth has been intensively studied, but little is known about what happens to carbon deep in the Earth.

“We are trying to understand more about whether carbon can be transported in the deep Earth through water-rich fluids,” said coauthor Dimitri Sverjensky, professor of earth and planetary sciences at Johns Hopkins University.

There is plenty of water in the mantle, the layer of the planet extending hundreds of miles below Earth’s crust, but little is known about how water behaves under the extreme conditions there — pressures run to hundreds of tons per square inch and temperatures are over 2,500 F.

Experiments reproducing these conditions are very hard to do, said Giulia Galli, professor of chemistry and physics at UC Davis and co-author on the paper. Geochemists have models to understand the deep Earth, but they have lacked a crucial parameter for water under these conditions: the dielectric constant, which determines how easily minerals will dissolve in water.

“When people use models to understand the Earth, they need to put in the dielectric constant of water — but there are no data at these depths,” Galli said.

Galli and Sverjensky are collaborators in the Deep Carbon Observatory, supported by the Alfred P. Sloan Foundation, which seeks to understand the role of carbon in chemistry and biology deep in the Earth.

Researchers have speculated that carbon, trapped as carbonate in the shells of tiny marine creatures, sinks to the ocean floor and gets carried into the mantle on sinking crustal plates then is recycled and escapes through volcanoes, Sverjensky said. But there has been no mechanism to explain how this might happen.

Ding Pan, a postdoctoral researcher at UC Davis, used computer simulations of water to predict how it behaves under extreme pressure and temperature. The simulations show that the dielectric constant changes significantly. By bringing that new factor into the existing models of water in the mantle, the researchers predict that magnesium carbonate, which is insoluble at Earth’s surface, would at least partially dissolve in water at that depth.

“It has been thought that this remains solid, but we show that at least part of it can dissolve and could return to the surface, possibly through volcanoes,” Sverjensky said. “Over geologic timescales, a lot of material can move this way.”

Sverjensky said the new modeling work was a “first step” to understanding how carbon deep in the Earth can return to the surface.

Other authors on the paper are Leonard Spanu, a postdoctoral researcher at UC Davis now at the Shell Technology Center in Bangalore, India; and Brandon Harris, research assistant at Johns Hopkins.

Launched in 2009, the Deep Carbon Observatory aims to achieve a better understanding of the “deep carbon cycle,” and a more complete understanding of the role of carbon on our planet.

The work was supported by the U.S. Department of Energy, the Sloan Foundation and by computational resources through the National Science Foundation.

Source: University of California – Davis [March 18, 2013]



Related articles

Yorkshire’s oldest campsite discovered

Yorkshire’s oldest campsite could have been unearthed in a national park. But this was no holiday destination. The...

Scottish road works unearth Iron Age village

An Iron Age village along with a host of ancient artefacts including tools and jewellery have been discovered...

An erotic epigram on an ostrakon from Rhodes

Love as a burden and other “daemons”. This is the theme of an epigram found on an ostrakon...

Delhi heritage sites to be restored

Mughal prince Dara Shikoh's library, the Malcha Mahal hunting lodge of Firoz Shah Tughlaq and some ancient gateways...

Oldest evidence of life on land found in 3.48 billion-year-old Australian rocks

Fossils discovered by UNSW scientists in 3.48 billion year old hot spring deposits in the Pilbara region of...

Two Harappan sites being excavated

Excavations have begun at the two Harappan sites of Binjor in Rajasthan, close to the India-Pakistan border, and...

Purana Qila dig reveals the many dynasties that ruled over Delhi

The 16th century Purana Qila is one of Delhi's’s most iconic monuments with its stone ramparts and moat....

Fossil of pregnant lizard discovered

A 120-million-year-old fossil is the oldest pregnant lizard ever discovered, according to scientists. The fossil, found in China,...