In late November, the ANDRILL drilling team passed the 3,000-foot mark in rock core pulled from beneath the sea floor in McMurdo Sound, and with a remarkable recovery rate of more than 98 percent. The expected final total should exceed more than 3,600 feet – the second-deepest rock core drilled in Antarctica.
A second season in Antarctica for the Antarctic Geological Drilling (ANDRILL) Program has exceeded all expectations, according to the co-chief scientists of the program's Southern McMurdo Sound Project.
In late November, the drilling team passed the 1,000-meter mark in rock core pulled from beneath the sea floor in McMurdo Sound, and with a recovery rate of more than 98 percent. The final total of recovered core is expected to exceed 3,600 feet. It's the second-deepest rock core drilled in Antarctica, surpassed only by the more than 4,215 feet recovered by last year's ANDRILL effort, the McMurdo Ice Shelf Project.
As the job nears completion for the Southern McMurdo Sound Project drillers, the co-chief scientists, David Harwood of the University of Nebraska-Lincoln and Fabio Florindo of Italy's National Institute of Geophysics and Volcanology in Rome, says they couldn't be more pleased with the results. They say the efforts of the program's nearly 80 scientists, drillers, engineers, technicians, students and educators in Antarctica, with the operations and logistics support provided by Antarctica New Zealand, have given the world's scientists more than a kilometer of pristine rock core that records the history of climate and glacial fluctuations in Antarctica over the past 20 million years.
"It's everything we hoped for," Harwood explains. "Combine the drill hole we recovered last year with this one, from a time period right below it, and it's more than 1 1/4 miles of geological history. It's phenomenal what we've recovered. There's a lot of diversity in the core, indeed more than we can digest right now. It will take some time to fully resolve the paleoenvironmental and dynamic paleoclimate information in the core."
The goal of this drilling project was sediment core retrieval from the middle Miocene Epoch when, for an extended period, Earth was warmer than today. Florindo and Harwood say they are especially pleased to have recovered such high-quality core from this target period.
"We now have a more complete core record from the middle Miocene and a step into a colder period of time, and that was one of our key targets," Florindo says. "It will tell an important story when we put together our recovery with the record of last season. This is exciting science and it will echo loudly in the scientific community."
The middle Miocene has long been held as one of the fundamental time intervals in development of the modern Antarctic ice sheets. It encompassed a change from a warm climate optimum approximately 17 million years ago to the onset of major cooling approximately 14 million years ago, and the formation of a quasi-permanent ice sheet on East Antarctica. Florindo and Harwood note that fossils and sediments deposited during this year's ANDRILL target interval suggest the persistence of warmer-than-present conditions over an extended period of the middle and late Miocene when the western Ross Sea and McMurdo Sound resembled the modern climate conditions of southernmost South America, southwestern New Zealand, and southern Alaska, rather than the cold polar climate of today.
"Until now, most climatic interpretations for this time period has been based on measurement of oxygen isotopes in the deep sea, far from Antarctica," Harwood says. "The cores we've recovered will give us a high resolution history of paleoclimate change directly from the Antarctic continent."
According to Florindo and Harwood, the sediment cores reflect deposition close to or beneath grounded glaciers, alternating with fine-grained sediments, which provide clear evidence for ice advance and substantial retreat during main climate transitions. They say programs like ANDRILL are extremely important because of the uncertainties about the future behavior of Antarctic ice sheets. This stratigraphic record will be used to determine the behavior of ancient ice sheets, and to better understand the factors driving past ice sheet, ice shelf and sea-ice growth and decay. This new knowledge will enhance our understanding of Antarctica's potential responses to future global climate changes.
After a seven-week setup period by Antarctica New Zealand during late winter in the Southern Hemisphere, drilling began in October and continued until the end of November, with the drillers recovering 80 feet to 230 feet of core each day. There only was one major interruption, occurring in early November when sand and water flowed into the drill hole, but Harwood reveals that the drill team "did an awesome job" of fixing the problem.
Following the planned drilling stoppage, scientists lowered a variety of scientific instruments into the deep drill hole over several days to get a better understanding of the physical properties of the geologic layers under pressure and to obtain an acoustic image of the inside of the borehole. Drilling then resumed, and continued for some days in order to recover nearly 330 feet of additional core.
The first stop for each core section after recovery is the Crary Science and Engineering Center, operated by the U.S. National Science Foundation at McMurdo Station. After preliminary examination by on-ice scientists, the cores are shipped to Florida State University's Antarctic Marine Geology Research Facility in Tallahassee for storage and long-term study.