New research may draw a 'curtain of fire' on dinosaur extinction theory
The role volcanic activity played in mass extinction events in the Earth's early history is likely to have been much less severe than previously thought, according to a study led by the University of Leeds.
Asteroid impacts and long-lasting volcanic eruptions called continental flood basalts -- the two most commonly cited possible causes of mass extinction events -- would have propelled gas and dust into the atmosphere and altered climate for years. But, until now, the impact of years of sulphur dioxide emissions from continental flood basalts was unknown.
In a study published online today in Nature Geoscience, researchers have provided for the first time a quantitative estimate of the degree and nature of the effects that such eruptions had on the Earth's climate, vegetation and oceans.
Study lead author Dr Anja Schmidt, from the University's School of Earth and Environment, said: "At the time when the dinosaurs reigned, numerous long-lasting eruptions took place over the course of about a million years. These eruptions, called 'continental flood basalts' were not like volcanic eruptions we often see today, with lava gushing from the ground like a curtain of fire.
"Each eruption is likely to have lasted years, even decades, and eruptions were separated by periods without volcanic activity. The lava produced by an eruption of average intensity would have filled 150 Olympic-size swimming pools per minute."
In the new study, the researchers used a sophisticated computer simulation of the spread of the gas and aerosol particles, which showed that the climatic impacts of flood basalts was less grim than scientists had previously suggested. They found that only if such flood basalts oozed for hundreds of years, without interruption, may the climatic impacts have had a severe effect on plants and animals.
The researchers used information on the duration and intensity of continental flood basalt eruptions, such as the Deccan Traps eruptions 65 million years ago, which covered one-third of what is now India, to estimate the climatic and environmental effects of the huge quantities of sulphur dioxide gas emitted by these eruptions.
Their computer simulation showed that temperatures on Earth were indeed cooler as a result of the eruptions -- by as much as 4.5 degrees Celsius -- but that the temperature would return to normal within 50 years after an eruption ceased.
Dr Schmidt noted that the conclusions are based on the assumption that climate feedbacks were very similar to those today.
"Perhaps most intriguingly, we found that the effects of acid rain on vegetation were rather selective. Vegetation in some but not all parts of the world would have died off, whereas in other areas the effects would have been negligible," said Dr Schmidt.
The new findings will challenge the earth sciences community as a whole to re-examine the causes of mass extinctions and the role of volcanism. "We now need to better understand how long both the individual eruptions and the periods without volcanic activity lasted," concludes Dr Schmidt.
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Further information
The research paper, 'Selective environmental stress from sulfur emitted by continental flood basalt eruptions', is published online by Nature Geoscience on 23 Nov. 2015.
Dr Anja Schmidt is available for interview.
Please contact the University of Leeds press office:
0113-34-4031
pressoffice@leeds.ac.uk.
Images
All files can be downloaded from here: https://goo.gl/SieeJn
Photo
Caption: Lava fountaining above the volcanic fissure of the Holuhraun flood basalt eruption in Iceland in Sept. 2014, which can be considered as a smaller scale analogue for the eruptions in the Deccan Traps, 65 million years ago.
Credit: Michelle Parks (University of Iceland)
Illustration
An artist's impression of a typical flood basalt eruption, including lava fountaining along a curtain of fire. New research shows that the climatic impacts of such eruptions were less grim than scientists had previously suggested, with most of the volcanic gases and aerosol particles confined to the lowermost atmosphere.
Credit: Jonathan Poulter
Journal
Nature Geoscience