U.S.-Canada Arctic Ocean Survey Partnership Saved Costs, Increased Data

2011 Mission Concludes Joint Seafloor Survey Operations

USCG Healy and the Canadian Coast Guard Ship Louis S. St-Laurent. working together.

(Credit: University of New Hampshire/NOAA)

A recent mission marked the completion of a five-year collaboration between the United States and Canada to survey the Arctic Ocean. The bilateral project collected scientific data to delineate the continental shelf beyond 200 nautical miles from the coastline, also known as the extended continental shelf (ECS).

The U.S. has an inherent interest in knowing, and declaring to others, the exact extent of its sovereign rights in the ocean as set forth in the Convention on the Law of the Sea. For the ECS, this includes sovereign rights over natural resources on and under the seabed including energy resources such as: oil and natural gas and gas hydrates; “sedentary” creatures such as clams, crabs, and corals; and mineral resources such as manganese nodules, ferromanganese crusts, and polymetallic sulfides. 

The 2011 joint Arctic mission spanned nearly six weeks in August and September and was the fourth year to employ flagship icebreakers from both countries, the U.S. Coast Guard Cutter Healy and the Canadian Coast Guard Ship Louis S. St-Laurent.

“This two-ship approach was both productive and necessary in the Arctic’s difficult and varying ice conditions,” said Larry Mayer, Ph.D., U.S. chief scientist on the Arctic mission and co-director of the NOAA-University of New Hampshire Joint Hydrographic Center. “With one ship breaking ice for the other, the partnership increased the data either nation could have obtained operating alone, saved millions of dollars by ensuring data were collected only once, provided data useful to both nations for defining the extended continental shelf, and increased scientific and diplomatic cooperation”.

Track lines for USCGC Healy showing seafloor sonar data from cruises from 2003 to date in the Arctic.

High Resolution (Credit: UNH/CCOM/NOAA)

Preliminary studies indicate the U.S. ECS, including the Arctic Ocean areas surveyed, total at least one million square kilometers, an area about twice the size of California. Additional data collection and analysis will lead to more accurate estimates of the extent of the U.S. ECS. 

U.S. ECS work is not limited to the Arctic and includes areas in the Bering Sea, Gulf of Mexico, the Atlantic, Gulf of Alaska, Marianas and Line Islands, as well as areas off northern California and northwest of Hawaii. In addition to Arctic survey work, the U.S. Geological Survey (USGS) led missions in 2011 to collect seismic data in the Gulf of Alaska and the Bering Sea, and scientists from the Joint Hydrographic Center collected bathymetric data northwest of Hawaii. NOAA and USGS funded the 2011 U.S. missions. Two U.S. ECS missions are planned for 2012, one in the Atlantic and one in the Arctic. 

“The amount and quality of the data collected as part of these joint Arctic missions met and often exceeded the expectations we would set each year,” said Deborah Hutchinson, Ph.D., a geologist with the USGS and U.S. science lead and liaison on board CCG Ship Louis S. St-Laurent.

This year’s U.S. Arctic mission was led by the Joint Hydrographic Center, a partnership between NOAA and the University of New Hampshire, while the Canadian mission was led by the Geological Survey of Canada of Natural Resources Canada.  

Scientists on board Healy used a multibeam echo sounder to collect bathymetric data to create three-dimensional images of the seafloor. Scientists aboard CCGS Louis S. St-Laurent collected seismic data to determine the thickness of the sediments under the seafloor and to better understand the geology of the Arctic Ocean. The 2011 Arctic mission traversed more than 5,600 total miles over the Beaufort Shelf, Chukchi Borderland, Alpha Ridge, and Canada Basin and reached more than 1,230 miles north of the Alaskan coast. 

 “As in previous Arctic missions, we obtained data in areas we were not entirely sure the ice would allow us to proceed, even with a two-ship operation,” said Andy Armstrong, co-chief scientist on the Arctic mission and co-director of the NOAA-University of New Hampshire Joint Hydrographic Center. “This was especially true in the eastern part of the Canada Basin where some of the thickest Arctic ice is found.”

3-D view of an isolated seamount discovered during Arctic Ocean sonar work in 2009. The feature rises from a depth of more than 3800 meters (nearly 12,500 feet) from the abyssal plain to a least depth of 2622 meters (8,600 feet). In the far background approximately 440 kilometers (240 miles)) away is the Chukchi Plateau.

High Resolution (Credit: CCOM/JHC University of New Hampshire/NOAA)

Data collected by these two nations tells other scientific stories for the first time. For example, USGS scientists collected baseline data on ocean acidification and scientists from the National Ice Center compared observed ice conditions with interpretations of the same ice seen on satellite imagery.

From 2006 to date, scientists on board CCGS Louis S. St-Laurent have collected nearly 15,000 kilometers (9,320 miles) of seismic data, vastly increasing the seismic data holdings in this area of the deep Arctic Ocean. Scientists from the United States and Canada are using these seismic data to revise models of the origin and tectonic evolution of this poorly understood portion of the ocean. 

Since the start of U.S. ECS work in the Arctic in 2003, Healy alone has mapped more than 320,000 square kilometers (123,000 square miles) of the Arctic seafloor, or about the size of Arizona. 

“These data provided high resolution maps to help determine the outer limits of the U.S. ECS, while revealing previously undiscovered mountains, known as seamounts, and scours created by past glaciers and icebergs scraping along the ocean bottom 400 meters below the surface,” said Mayer.

The U.S. Extended Continental Shelf Task Force is responsible for delineating the U.S. ECS and is chaired by the Department of State with co-vice chairs from the National Oceanic and Atmospheric Administration and the Department of the Interior. Ten additional agencies participate in the task force, including the U.S. Geological Survey, Joint Chiefs of Staff, U.S. Navy, U.S. Coast Guard, Department of Energy, National Science Foundation, Environmental Protection Agency, Bureau of Ocean Energy Management, the Arctic Research Commission, and the Executive Office of the President. Additional information on the joint U.S.-Canadian Extended Continental Shelf cruise is available at http://www.continentalshelf.gov andhttp://ess.nrcan.gc.ca/scient_e.php.

Active 2011 hurricane season breaks 'Hurricane Amnesia'

Irene the first hurricane to hit U.S. in three years; Northeast reminded it’s also vulnerable

The 2011 Atlantic hurricane season officially ends Wednesday, having produced a total of 19 tropical storms of which seven became hurricanes, including three major hurricanes. This level of activity matched NOAA’s predictions and continues the trend of active hurricane seasons that began in 1995.

The 19 tropical storms represent the third-highest total (tied with 1887, 1995, and 2010) since records began in 1851 and is well above the average of 11. However, the number of hurricanes and major hurricanes is only slightly above the average of six and two, respectively. This year’s totals include a post-storm upgrade of Tropical Storm Nate to hurricane status, and the addition of a short-lived, unnamed tropical storm that formed in early September between Bermuda and Nova Scotia. This unnamed storm, along with several other weak, short-lived named storms, could have gone undetected without modern satellite technology.

Irene was the lone hurricane to hit the United States in 2011, and the first one to do so since Ike struck southeast Texas in 2008. Irene was also the most significant tropical cyclone to strike the Northeast since Hurricane Bob in 1991.

“Irene broke the ‘hurricane amnesia’ that can develop when so much time lapses between landfalling storms,” said Jack Hayes, Ph.D., director of NOAA’s National Weather Service. “This season is a reminder that storms can hit any part of our coast and that all regions need to be prepared each and every season.”

As far as landfalling major hurricanes (Category 3, 4 or 5 with top winds of 111mph and greater) are concerned, the lull continues. 2011 marks a record six straight years without one hitting the United States. The last one to do so was Wilma in 2005. Nonetheless, wind is not the only threat with tropical systems as proven by Irene and Lee, which caused deadly and destructive flooding. On average, more than half of the fatalities related to tropical systems are due to flooding.

Hurricane Irene is an example of increasing accuracy in forecasting storm track. Its landfall in eastern North Carolina and path northward were accurately predicted more than four days in advance by NOAA’s National Hurricane Center using information from weather satellites, hurricane models, aircraft observations, and other data. NOAA’s delivery of critical environmental forecasts provided essential advance information that allowed emergency officials to plan necessary evacuations and sparked individuals to take safety precautions. But a weaker-than-anticipated Irene at landfall also highlighted the challenges that remain in forecasting storm intensity.

“Improving intensity forecasts is a focus of ongoing research and is part of NOAA’s Hurricane Forecast Improvement Project,” said Frank Marks, Ph.D., director of NOAA’s Hurricane Research Division. HFIP bridges research and operational components to better anticipate rapid changes in storm intensity and its goal to extend track forecasts from the current five days to seven days.

“Although the 2011 hurricane season has ended, our need to prepare for disasters hasn't,” said Craig Fugate, administrator of the Federal Emergency Management Agency. “Being prepared for all kinds of hazards, from hurricanes to blizzards to tornadoes, is a year-round activity. We encourage all members of the team, especially the public, to continue to prepare for emergencies by staying informed of forecasted weather events, making an emergency plan, and building your emergency preparedness kit. Visit Ready.gov to learn more.”

NOAA will issue its initial outlook for the 2012 hurricane season in May just prior to the official start of the season on June 1.

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