December 16, 2019
University of Michigan
The impact of an asteroid or
comet is acknowledged as the principal cause of the mass extinction that killed
off most dinosaurs and about three-quarters of the planet's plant and animal
species 66 million years ago.
The impact of an asteroid or
comet is acknowledged as the principal cause of the mass extinction that killed
off most dinosaurs and about three-quarters of the planet's plant and animal
species 66 million years ago.
But massive volcanic eruptions
in India may also have contributed to the extinctions. Scientists have long
debated the significance of the Deccan Traps eruptions, which began before the
impact and lasted, on and off, for nearly a million years, punctuated by the
impact event.
Now, a University of
Michigan-led geochemical analysis of fossil marine mollusk shells from around
the globe is providing new insights into both the climate response and
environmental mercury contamination at the time of the Deccan Traps volcanism.
From the same shell specimens,
the researchers found what appears to be a global signal of both abrupt ocean
warming and distinctly elevated mercury concentrations. Volcanoes are the
largest natural source of mercury entering the atmosphere.
The dual chemical fingerprints
begin before the impact event and align with the onset of the Deccan Traps
eruptions.
When the researchers compared
the mercury levels from the ancient shells to concentrations in freshwater clam
shells collected at a present-day site of industrial mercury pollution in
Virginia's Shenandoah Valley, the levels were roughly equivalent.
Evidence from the study, which
is scheduled for publication Dec.16 in the journal Nature Communications,
supports the idea that Deccan Traps volcanism had climatic and ecological
impacts that were profound, long-lasting and global, the researchers conclude.
"For the first time, we
can provide insights into the distinct climatic and environmental impacts of
Deccan Traps volcanism by analyzing a single material," said Kyle Meyer,
lead author of the new study. "It was incredibly surprising to see that
the exact same samples where marine temperatures showed an abrupt warming
signal also exhibited the highest mercury concentrations, and that these
concentrations were of similar magnitude to a site of significant modern
industrial mercury contamination."
Meyer conducted the study as
part of his doctoral dissertation in the U-M Department of Earth and
Environmental Sciences. He is now a postdoctoral researcher at Portland State
University in Oregon.
Mercury is a toxic trace metal
that poses a health threat to humans, fish and wildlife. Human-generated
sources of mercury include coal-fired power plants and artisanal gold mines. At
Virginia's South River industrially contaminated site, where the researchers
collected freshwater clam shells, signs warn residents not to eat fish from the
river.
"The modern site has a
fishing ban for humans because of high mercury levels. So, imagine the
environmental impact of having this level of mercury contamination globally for
tens to hundreds of thousands of years," said U-M geochemist and study
co-author Sierra Petersen, who was Meyer's co-adviser.
The researchers hypothesized
that the fossilized shells of mollusks, principally bivalves such as oysters
and clams, could simultaneously record both coastal marine temperature
responses and varying mercury signals associated with the release of massive
amounts of heat-trapping carbon dioxide and mercury from the Deccan Traps.
The long-lived Deccan Traps
eruptions formed much of western India and were centered on the time of the
Cretaceous-Paleogene (K-Pg) mass extinction, 66 million years ago.
The study used fossil shells
collected in Antarctica, the United States (Alabama, Alaska, California and
Washington), Argentina, India, Egypt, Libya and Sweden. The researchers
analyzed the isotopic composition of the shell carbonate to determine marine
temperatures, using a recently developed technique called carbonate clumped
isotope paleothermometry.
They also measured the amount
of mercury in the remarkably well-preserved fossil shells and assembled the
first-ever deep-time record of mercury preserved in fossilized biomineral
remains.
In previous studies, records
of environmental mercury have been reconstructed from marine sediments,
providing insights into the timing and scale of the Deccan Traps event. But
those records lacked such a direct linkage to the climate response. In the new
study, both signals are present in the same specimens -- an important first,
according to the authors.
"Mercury anomalies had
been documented in sediments but never before in shells. Having the ability to
reconstruct both climate and a volcanism indicator in the exact same materials
helps us circumvent lots of problems related to relative dating," said
Petersen, an assistant professor in the U-M Department of Earth and
Environmental Sciences. "So, one of the big firsts in this study is the
technical proof of concept."
The new technique is expected
to have broad applications for the study of mass extinctions and climate
perturbations in the geological record, according to the researchers.
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