新澳门六合彩内幕信息

Buried Alive: Carbon Dioxide Release From Magma Deep Beneath Ancient Volcanoes a Hidden Driver of Earth鈥檚 Past Climate

鈥淐ryptic Carbon鈥 From Underground Portions of Enormous Volcanic Provinces Contributed to Climate Warming in Earth鈥檚 Past

Blogs
Outdoor scene of a cliff of rock with mountains in the background. Small human figures can be seen at the base of the cliff.
Scientists examine a large dike, formed from a sheet of magma that came to Earth鈥檚 surface millions of years ago during the Columbia River Basalt eruptions. These dikes fed magma to massive eruptions. New research shows that long after the eruptions ended, carbon dioxide continued to seep to the surface, causing prolonged warming of Earth's climate. (Benjamin Black/Rutgers University)

An international team of geoscientists led by a volcanologist at Rutgers University-New Brunswick and including Maxwell Rudolph, associate professor in the 新澳门六合彩内幕信息 Davis Department of Earth and Planetary Sciences, has discovered that, contrary to present scientific understanding, ancient volcanoes continued to spew carbon dioxide into the atmosphere from deep within the Earth long past their period of eruptions.

In doing so, the research team has solved a long-standing mystery over what caused prolonged episodes of warming during turning points in Earth鈥檚 climate history. The work is detailed in today鈥檚 (Oct. 30) issue of the journal .

鈥淥ur findings are important because they identify a hidden source of CO2 to the atmosphere during moments in Earth鈥檚 past when climate has warmed abruptly and stayed warm much longer than we expected,鈥 said Benjamin Black, who led the study and is an associate professor in the Department of Earth and Planetary Sciences at the School of Arts and Sciences. 鈥淲e think we have figured out an important piece of the puzzle for how Earth鈥檚 climate was disrupted, and perhaps just as importantly, how it recovered.鈥

In the present-day, humans are releasing vastly more carbon dioxide than all active volcanoes put together鈥攂ut the new findings could shed light on how the planet鈥檚 climate will recover if and when human carbon dioxide emissions decrease. 鈥淓arth has natural climate control systems 鈥 sort of like the thermostat in your house,鈥 Black said. 鈥淭he question is鈥攁re there thresholds beyond which those climate control systems start to break down, making it much harder for climate to recover?鈥

For decades, scientists have been baffled by climate records showing the failure of the Earth鈥檚 atmosphere to recover as quickly as expected after what is known as the end-Permian mass extinction 252 million years ago 鈥 the most severe decrease in biodiversity known to have occurred on Earth. The mass extinction has been linked with tremendous volcanic eruptions in Siberia. Even after the eruptions ceased, Earth's climate took nearly 5 million years to stabilize.

鈥淭his delayed recovery has long puzzled scientists. Earth鈥檚 natural thermostat seems to have gone haywire during and after this event,鈥 Black said. 鈥淲e noticed that a similar pattern seemed to have occurred at multiple other times in Earth鈥檚 history with massive volcanism, and we set out to understand why.鈥

Modeling carbon emissions from magma

Black and an international team of colleagues looked back in time and found evidence for carbon dioxide emissions from this type of volcanic province that could last millions of years after most surface eruptions had ended. They did this by compiling chemical analyses of the lavas, developing computer models simulating melting inside the Earth, and comparing the results with records of past climate preserved in sedimentary rocks.

Rudolph modeled the amount of magma (molten rock) and the amount of CO2 generated within a rising mantle plume. These models provide a range of values for the total mass of carbon released to the atmosphere as well as the rate at which it is released, he said. 

鈥淥nce it is released from mantle rocks, some of the carbon can migrate upward through Earth's crust and eventually to the atmosphere. However, the crust acts as a filter, storing some of the ascending magma, where it stays behind and crystallizes rather than rising to the surface and erupting as lava flows,鈥 Rudolph said.

The analyses showed that massive ancient volcanic provinces shut down slowly. At the surface, eruptions may have stopped, but deep in the crust and mantle, magma was still releasing carbon dioxide, leading to prolonged climate warming.

鈥淲e call this CO2 from the subsurface magma 鈥榗ryptic carbon鈥 because it comes from magmas lurking deep in the system,鈥 Black said. 鈥淚t鈥檚 as if the volcanoes were releasing carbon from beyond the grave.鈥

Black said the findings in the new study are significant because they identify a hidden source of atmospheric carbon dioxide during moments when the climate warmed abruptly. If the volcanoes kept 鈥渢urning the temperature up,鈥 it could mean the Earth鈥檚 thermostat may work better than scientists thought.

Black emphasized that cryptic carbon from volcanoes cannot explain present-day climate change. 鈥淭he type of volcanism we are investigating is rare, capable of generating enough magma to cover the continental United States half a kilometer deep in lava,鈥 Black said. 鈥淭his kind of volcanism has not occurred for 16 million years. All the volcanism taking place on the planet today releases less than one percent as much carbon dioxide as human activities.鈥

But scientists still hope to learn from these past eruptions about current and future climate. 鈥淭hese ancient eruptions appear to be some of the only events in Earth鈥檚 history that release carbon on the same scale as humans are doing today,鈥 Black said. 鈥淪o by studying these eruptions in the deep past we can learn more about how Earth鈥檚 climate systems respond to massive release of carbon to the atmosphere.鈥

These findings are just the beginning of a multi-year effort funded by the National Science Foundation to investigate how cryptic carbon could influence recovery after major disruptions of Earth鈥檚 climate. 

Other scientists on the study included: Leif Karlstrom of the University of Oregon; Benjamin Mills of the University of Leeds, Leeds, UK; Tamsin Mather, University of Oxford, Oxford, UK; Jack Longman, Northumbria University, Newcastle Upon Tyne, UK; and Andrew Merdith, University of Adelaide, Adelaide, Australia.

Media Resources

(Nature Geoscience)

Adapted from a issued by Rutgers University - New Brunswick. 

Kitta MacPherson is a senior public relations specialist at Rutgers University. 

 

Primary Category

Secondary Categories

Science and Climate

Tags