A convoy of bulldozers and trucks has set out from a remote airport in Siberia, heading for a frozen lake 62 miles north of the Arctic Circle, but the trip wasn’t a holiday visit to the North Pole. Instead, the trucks are delivering core-drilling equipment for a study of sediment and meteorite-impact rocks that should provide the longest time-continuous climate record ever collected in the Arctic.
Once in place this month, the drilling will allow an international team led by
Geosciences professor Julie Brigham-Grette and Martin Melles of the University
of Cologne, Germany, to burrow back in time, retrieving core samples more than
3 million years old and answering questions about Earth’s ancient past.
Almost impossibly remote, Lake El’gygytgyn, 11 miles in diameter, was formed
3.6 million years ago when a monster meteor, more than a half-mile across,
slammed into the Earth between the Arctic Ocean and the Bering Sea. Because
this part of the Arctic was never covered by ice sheets or glaciers, it has
received a steady drift of sediment – as much as a quarter mile (1,312 feet)
deep – since impact. Thus, it offers a continuous depositional record unlike
any other in the world, say Brigham-Grette and colleagues, beneath the crater
lake that’s more than 560 feet deep, equal to the height of the Washington
The convoy is taking 25 days to crawl through the frozen dark, building a
224-mile ice road as they go, over which the heavy drilling equipment can be
moved from the remote airstrip at Pevek, in the north of Russia’s Chukotka
Autonomous Region. “Lake El’gygytgyn is logistically among the most difficult
places on Earth to carry out a scientific drilling program,” Brigham-Grette
acknowledges. But by all accounts, the rewards should be worth all the effort.
In preparation for this day, scientists from institutes in Germany, Russia and
Austria, as well as the geosciences department have been flying in by
helicopter for focused tests over the past 10 years, drilling pilot cores and
taking other samples and measurements. The site has passed every test. For
example, the lake bed has been undisturbed by earthquakes, other underground
shifting or drying for thousands of years. Pilot cores of 54 feet long already
have provided a snapshot of climate from 300,000 years ago.
El’gygytgyn thus offers a truly unprecedented and ideal opportunity, Brigham-Grette
notes, for piecing together a clearer picture of the hemisphere’s prehistoric
climate and the dynamic processes of global climate change since the meteor’s
impact. Notably, the researchers hope they can learn more about the unexplained
shift from a warm forest ecology to permafrost, some 2 million to 3 million
years ago. Comparing cores from under Lake El’gygytgyn to those from lower
latitudes will help the climate scientists with a high-resolution tool to study
climatic change across northeast Asia “at millennial timescales,”
Brigham-Grette says. In addition to climate data, cores may offer the
researchers an opportunity to study the 3.6-million-year-old “impact breccia,”
that is, how Earth’s bedrock responded to the meteor’s impact.
Some sampling began in November at the science camp drilling site on the
lakeshore, where researchers will study the climate history of the permafrost
that surrounds the lake. The other two drill sites will be in the deepest part
of the lake. Waiting until Arctic winter to transport and install the
equipment, the team can use the frozen lake surface to support drills specially
designed to withstand the extreme weather conditions. The scientists plan to
start drilling overlapping cores at these frigid locations in February, using
the windswept lake ice as a drilling platform. Sampling will continue until
next May as part of the International Continental Scientific Drilling Program.
To ensure the safety of both scientists and drill-team members on the isolated
lake in potentially life-threatening conditions, Brigham-Grette and colleagues
have scrutinized how the ice shifts, cracks and responds to heavy wind and
circulation forces before settling on rig placement. Workers and scientists
will live in a protected personnel carrier that also will transport cores from
the rig on the lake ice to the science camp on the shore.
Sediment cores will be processed for shipment and stored at the lake in a
temperature-controlled container until they can be flown to St. Petersburg and
later trucked to the University of Cologne for study by the international team.
An “archive half” of each core also will be stored at the University of
Geoscientists Drill for Ancient Climate Secrets in Siberia
January 12, 2009