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University using new tech to record Antarctic Ocean, ice temps

Climate change effects to be monitored continuously with new fiber-optic distributed temperature sensing

University using new tech to record Antarctic Ocean, ice temps

Climate change effects to be monitored continuously with new fiber-optic distributed temperature sensing

Half-mile long thermometers have been dropped through the Ross Ice Shelf in Antarctica that will give the world relevant data on sea and ice temperatures for tracking climate change and its effect on the glacial ice surrounding the continent. The study based at the University of ÁùºÏ±¦µä, Reno is funded by the National Science Foundation's Office of Polar Programs and other NSF grants.

"This technology is allowing us to do something never before done; to record continuous temperature data in and under the ice shelf," said Scott Tyler of the University of ÁùºÏ±¦µä, Reno, who led the team of researchers at the desolate spot about 25 kilometers from the McMurdo Station research outpost. "The ice shelves serve as the 'corks' holding the large glaciers of west Antarctica from sliding into the ocean and raising sea level."

"The melting of the ice shelves from below by warmer ocean water represents a critical unknown in the assessment of Antarctic ice sheet collapse and the potential for very rapid sea level rise around the world. This will allow us to assess the potential for collapse," he explained.

Tyler, a professor in the University's College of Science, said the objectives of this first field season were to test the drilling design, test the fiber-optic installation and sensing and test the logistics of continuous monitoring and power system development for a full year of operation in the harsh Antarctic climate.

"The instruments are all ready for the winter now, with wind power, solar and camera set to record ocean temperatures through the seasons," he said. "We're already getting data downloads here at home eight times a day and the system is recording and sending temperatures and pressures perfectly. Our goals are to show that we can install these monitoring systems quickly and inexpensively, and then provide continuous data via satellite links throughout the long Antarctic winter."

The system continuously records temperature every meter along the cable, which is made from standard telecommunications fiber-optic cable surrounded by armoring to withstand the harsh pressures and conditions of the Antarctic Ocean. After drilling 200 meters through hard ice, the team lowered 800 meters of cable, reaching the ocean bottom where it also can measure the currents. A second hole through the ice was drilled and the cable end was suspended about 50 meters below the ice shelf.

"We have fantastic data so far, showing a uniform ocean temperature at the freezing point of sea water, with warm water likely to appear at the ice-ocean interface in a month or so," he said. "Amazing temperatures, from a cold of minus 22 C near the ice shelf surface (the annual average air temperature in the region), an exponential increase to the ocean at minus 1.9 C and then in the ocean a constant minus 1.9 C. We expect to see about a 1.5-meter loss in ice thickness over the summer."

In addition to the data dumps throughout the day, the system will send photos of the installation from a stationary camera mounted on a tower at the unmanned site. The camera will allow them to see if the equipment withstands the harsh weather at Windless Bight, so named by early explorers Shackleton and Scott for the occasional periods of calm in an otherwise windy area.

The site is on the McMurdo Ice Shelf, a subsidiary of the Ross Ice Shelf. It was chosen to provide realistic ice sheet thickness and sufficient ocean depth and ease of logistics to adequately test power supply viability and data communications.

Members of the team working with Tyler on the expedition were David Holland of New York University, Victor Zagorodnov of The Ohio State University and Alon Stern of New York University.

Tyler pioneered the fiber-optic DTS systems for academic research three years ago. He and his colleagues have since used innovative fiber-optic/laser technology to take temperatures around the world in a variety of hydrological, climatological and geological topics such as to study glaciers, caves, creeks, mines, avalanche areas, volcanoes, farmlands and even water temperature at Devils Hole in Death Valley to help protect the endangered pupfish.

For more information about distributed temperature sensing and its worldwide use to monitor the earth's temperature, visit or an article on University's Media Newsroom.

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